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Novel carbon-based sorbents for elemental mercury removal from gas streams: A review
Journal Pre-proofs Review Novel Carbon-based Sorbents for Elemental Mercury Removal from Gas Streams: A Review Dongjing Liu, Chaoen Li, Jiang Wu, Yangxian Liu PII: DOI: Reference:
S1385-8947(19)32929-8 https://doi.org/10.1016/j.cej.2019.123514 CEJ 123514
To appear in:
Chemical Engineering Journal
Received Date: Revised Date: Accepted Date:
14 September 2019 12 November 2019 15 November 2019
Please cite this article as: D. Liu, C. Li, J. Wu, Y. Liu, Novel Carbon-based Sorbents for Elemental Mercury Removal from Gas Streams: A Review, Chemical Engineering Journal (2019), doi: https://doi.org/10.1016/j.cej.2019.123514
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1
Novel Carbon-based Sorbents for Elemental Mercury Removal from
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Gas Streams: A Review
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Dongjing Liu 1, Chaoen Li 2, Jiang Wu 3, Yangxian Liu 1*
4 5 6 7
1 School
of Energy and Power Engineering, Jiangsu University, Zhenjiang 212013, China
2 College 3 College
of Mechanical Engineering, Tongji University, Shanghai 200092, China
of Energy and Mechanical Engineering, Shanghai University of Electric Power, Shanghai 200090, China
8 9 10
*Contact information: Tel.: +86-0511-88780211; Fax: +86-0511-88780211;
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E-mail: [email protected] (X.Y. Liu)
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Abstract: Mercury emission, derived from natural gas exploitation, metal sintering, coal
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gasification and combustion, gold mining, etc., has posed great threaten to the environment and
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human beings due to its volatility, mobility, toxicity, and bioaccumulation in ecosystem and food
16
chains. Adsorption using carbon materials is regarded as one of the most promising techniques for
17
mercury emission control due to its simple equipment, convenient operation, high removing
18
efficacy, less secondary pollution, etc. This review comments the new research progress of
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elemental mercury capture by novel carbon-based sorbents in recent five years, particularly
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emerging carbon materials, such as bio-chars, graphene and graphene oxide, carbon nanotubes and
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nanofibers, carbon spheres, carbon aerogels, metal-organic frameworks, and graphitic carbon
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nitrides. The mercury removal performances and reaction mechanisms of diverse carbon-based
1
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sorbents along with their merits and drawbacks are fully discussed, which aims to strengthen the
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understanding of this emerging research topic and outline future research directions for the
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development of sustainable, recyclable, and cost-effective carbon-based mercury sorbents.
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Keywords: Elemental mercury; graphitic carbon nitride; metal-organic framework; graphene;
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carbon sphere; bio-char
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1. Introduction
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Mercury, as a trace heavy metal element, is one of the primary lethal pollutants due to its
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toxicity, mobility and bioaccumulation in ecosystem and food chains [1-3]. Inorganic mercury can
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be methylated biotically to its most toxic form, dimethyl mercury which can cause nervous system
32
disorder, kidney and liver damage, and impair childhood development [4-5]. Mercury is naturally
33
abundant in coal and heavy metal-rich geologic deposits; however, it has been largely liberated into
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the atmosphere by human productive activities, such as natural gas exploitation, coal gasification
35
and combustion, metal sintering, gold mining and so forth [6-8]. Hence, abatement of
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anthropogenic mercury emissions from gas streams, such as natural gas, coal-fired flue gas, syngas,
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sintering gas, etc., has gained increasingly environmental and regulatory concern. The released
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mercury primarily existed in three forms, i.e. elemental mercury (Hg0), oxidized mercury (Hg2+)
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and particulate bond mercury (Hgp) [9-11]. Hg2+ species is easily absorbed by amine solution. Hgp
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can be readily captured by baghouse, electrostatic precipitator or fabric filter. However, Hg0 is
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hardly removed because of its high volatility and insolubility [12-14]. Therefore, efficient mercury
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control technologies are urgently needed. Currently, there are a number of technologies available to
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remove Hg0 from gas streams, for instance, wet advanced oxidation [15-17], catalytic oxidation
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[18-20], photochemical oxidation [21-23], and adsorption method [24-26]. Adsorption technology,
2
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characterized by simple equipment, convenient operation, good removing efficacy, and less
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secondary pollution, appears to be one of the most effective pathway to remove Hg0 from gas
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streams at low temperature. Because of its large surface area, flexible surface chemistry, and variety
48
diversity, carbon material is regarded as the most promising sorbent for mercury abatement [27-29].
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The recent advances in Hg0 removal techniques have been summarized by some researchers.
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Liu et al. [30] first comprehensively commented the progress of four types of advanced oxidation
51
technologies for Hg0 removal. The reaction mechanism, kinetics, reactor types and process system
52
as well as their effects on Hg0 abatement were evaluated, with insights into the challenges of
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large-scale application. Sowlat et al. [31] systematically discussed the effects of different
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calcinating temperatures, reaction temperatures, and flue gas components on the Hg0 removal
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performances of cerium-modified activated carbons. Xu et al. [32] reviewed the development of
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sorbent modification methods for Hg0 removal. The merits and shortcomings of diverse
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modification routes, such as halide and sulfur modification, acid and alkaline impregnation, noble
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metal and metal oxide decoration, microwave and plasma treatment, and miscellaneous
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modification were fully discussed. Yang et al. [33] highlighted the progress in Hg0 removal by
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gas-solid heterogeneous oxidation method from the perspective of key process parameters, reaction
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mechanisms, and properties of catalysts or traditional sorbents. Chalkidis et al. [34] critically
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commented the conventional and alternative sorbents as well as the processes adopted for mercury
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abatement and remediation during natural gas processing. Liu et al. [35] discussed the advances in
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Hg0 removal by mineral sorbents. The physiochemical features and common modification
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approaches for various mineral materials were briefly summarized. The influencing factors and
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possible reaction mechanisms with respect to Hg0 capture by mineral sorbents were highlighted.
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However, most of these reviews mainly paid attention on conventional activated carbons,
68
metallic oxides, and mineral sorbents in perspective of processes and kinetics. Due to the rapid
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development of material synthesis method and nanotechnology, many novel carbon-based polymers
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or composites have been applied for Hg0 removal due to their unique physicochemical properties. In
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this work, the research progress of Hg0 capture by novel carbon-based materials in recent five years,
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especially emerging carbon materials, such as bio-chars, graphene and graphene oxide, carbon
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nanotubes and nanofibers, carbon spheres, metal-organic frameworks, graphitic carbon nitrides, and
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carbon aerogels, are reviewed. The mercury removal performances and reaction mechanisms of
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diverse carbon-based sorbents associated with their merits and drawbacks are fully commented as
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well.
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2. Activated carbon
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Activated carbon is the most widely used mercury sorbent due to the merits of high surface
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area, favorable pore structures, and sufficient surface oxygen functional groups [36]. Raw activated
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carbon usually shows limited Hg0 removal performance, which can be greatly enhanced by halide,
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metal oxide, and sulfide modification [37-39].
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Halides have been extensively employed as modifiers for activated carbon sorbents. The
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efficiency of halogen-modified activated carbon for Hg0 removal increases in the order Cl < Br < I
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[40]. As for metal chlorides, FeCl3 is evidenced as the most effective modifier for activated carbon
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as compared to CuCl2, CeCl3, and MnCl2 [41]. The reaction mechanism of metal chlorides and
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elemental mercury has been widely studied. Chen et al. [42] claimed that the cupric and chloride in
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CuCl2-impregnated activated carbon had a cooperative effect, which significantly enhanced the Hg0
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removal performance. Tong et al. [43] proposed that I2 was the major active sites of
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KI-impregnated activated carbon for mercury removal. A high efficient I-modified activated carbon
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was prepared via iodine vapor deposition [44]. The Hg0 capture ability of I-modified activated
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carbon was superior to the one modified by bromide deposition. Besides, ZnCl2 in-situ activation
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could also greatly improve the Hg0 removal efficiency of the activated carbon owing to the
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production of ZnO [45].
94
However, halide-modified activated carbon often suffers from low thermal stability and
95
corrosion effect to the duct because of the release of halides at elevated temperatures. Therefore,
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precious metals and transition-metal oxides had been regarded as alternative modifying reagents for
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activated carbons due to their high thermal stability and excellent redox property. Three types of Pd
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species were identified in Pd-loaded activated carbon, i.e. Pd0, Pd2+ and Pd2H, among which Pd0
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was recognized as the dominant active species for Hg0 removal [46]. Presence of H2 promoted Hg0
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adsorption attributed to PdO reduction. However, existence of H2 and O2 disfavored mercury
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removal probably owing to the formation of inactive Pd(OH)2 and PdO, respectively. The presence
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of PdO would decrease Pd0 content; in addition, PdO was easily sulfided by H2S. Han et al. [47]
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pointed out that Fe addition could enhance the Hg0 removal performance of Pd-loaded activated
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carbon. Fe2O3 could compete with PdO to react with H2S, thus protecting sorbent from H2S
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poisoning. Au-loaded activated carbon also displayed good ability towards Hg0 adsorption due to
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the formation of Hg-Au amalgam [48].
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Though precious metal-modified activated carbon had good Hg0 removal performance, the
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high capital costs and scarce sources of noble metals still restrained their large-scale application.
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Thus, inexpensive transition-metal oxides have attracted increasing research concern recently. A
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sequence of CeO2-MnOx modified activated carbons were used to remove Hg0 at low temperature
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[49]. The existence of the Ce4+/Ce3+ redox couple and multiple valence states of Mn ions enhanced
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the Hg0 oxidation ability of the activated carbon. CeO2-V2O5 modified activated carbons were also
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applied for Hg0 capture at 100-200 °C [50]. V2O5 and CeO2 displayed the optimal cooperative
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effect towards Hg0 oxidation with 1 wt% V2O5 and 8 wt% CeO2 in the sorbent. However, most
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transition-metal oxides showed lower SO2 resistance, especially manganese oxides [51].
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Recently, metal sulfides are considered as effective modifying reagents for activated carbons
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due to their higher thermal stability and stronger affinities towards elemental mercury compared to
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halides, precious metals, and transition-metal oxides. Yang et al. [52] found that copper polysulfide
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modified activated carbon displayed better Hg0 removal performance and higher SO2 resistance
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than those of copper or sulfur modified ones. The process of Hg0 adsorption on copper polysulfide
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modified activated carbon is presented in Fig. 1. First, Hg0 was physically adsorbed on sorbent
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surface. Then, the adsorbed Hg0 bonded with the active sulfur species in copper polysulfide to
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generate stable HgS.
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Fig. 1 The process of Hg0 capture from flue gas by copper polysulfide modified activated carbon
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(AC).
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A ZnS-modified activated carbon was attained by in-situ calcination of high sulfur-containing
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petroleum coke and zinc nitrate under nitrogen atmosphere [53]. It sustained Hg0 removal efficiency 6
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>84% within 360 min at or below 120 °C. But Hg0 removal was inhibited by rising reaction
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temperature. H2S greatly enhanced Hg0 capture performance of the ZnS-modified activated carbon,
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while H2S content had nearly no influence on Hg0 removal efficiency. Shi et al. [54] employed
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non-thermal plasma to modify activated carbons in the presence of H2S to enhance Hg0 removal
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performance. Sulfur content and Hg0 removal efficiency augmented with incremental H2S content.
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The enhancement of Hg0 capture performance was due to the chemisorption rather than
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physisorption. Hg0 was removed by binding with the sulfur species on the surface of activated
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carbon, which yielded HgS.
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3. Activated coke
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Activated coke is a kind of porous carbon-based sorbent, which is not fully activated or
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retorted as compared to activated carbon [55]. Activated coke owns higher mechanical strength,
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better regenerability, and lower capital cost than activated carbons, making it a promising candidate
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for mercury removal. It can also resist abrasion and crushing during circulation and handling
142
processes because of its high mechanical strength [56].
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MnOx-CeO2 modified activated coke showed good Hg0 oxidation ability, which was plausibly
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ascribed to the lattice oxygen and chemisorbed oxygen or hydroxyl groups on sorbent surface [57].
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The CoOx-CeO2 modified activated coke also performed well towards Hg0 removal, which was
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attributed to the synergetic effect between CoOx and CeO2 [58]. Zhao et al. [59] employed
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copper-modified activated coke for Hg0 removal. Copper nitrates would decompose into CuO at
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lower calcinating temperatures, and partially into Cu2O at higher temperatures. Furthermore, copper
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decoration broadened the pore distribution of the activated coke, benefiting Hg0 removal. The
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adsorbed mercury species on sorbent surface were identified as Hg0 and HgO, testifying that the
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mechanism of Hg0 removal by Cu-modified activated coke was a combination of adsorption and
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oxidation.
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Chen et al. [60] used CoOx-CeO2 modified activated coke to simultaneously remove Hg0 and
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HCHO. The good texture property, high dispersion of CoOx and strong redox ability contributed to
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its good removal performances of Hg0 and HCHO. Furthermore, the interaction between CoOx and
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CeO2 facilitated the mobility of the active oxygen species, significantly promoting the removal
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performances of Hg0 and HCHO. Liu et al. [61] reported that MoO3-CeO2 loaded cylindrical
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activated coke with Mo/Ce molar ratio of 1:2 performed the best towards Hg0 removal with good
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stability and remarkable resistance to SO2 and H2O, which was attributed to the synergy effect of
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Mo6+ and Ce3+ ions. The possible reason for its high SO2 tolerance was as follows: (i) the
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preferential interaction between sulfate and MoO3 prevented ceria from SO2 poisoning; (ii) the
162
presence of SO2 resulted in the generation of weakly-HgO and HgSO4, appreciably promoting Hg0
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removal. Mn-Ni co-loaded activated coke also displayed good Hg0 removal performance with
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Mn/Ni ratio of 6:0.5. [62].
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Semi-coke, as potentially inexpensive mercury sorbent, owns high mechanical strength,
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well-developed pore structures, and abundant surface functional groups [63]. Fe-Ce modified lignite
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semi-coke showed good Hg0 oxidation ability with the optimal Fe/Ce molar ratio of 0.4:0.2. H2S
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reacting with Fe-Ce oxides yielded active sulfur, benefiting Hg0 removal via generating HgS [64].
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However, the presence of exorbitant H2S restrained Hg0 removal, because excessive reaction of H2S
170
with Fe-Ce oxides would consume active metal oxides.
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Zhang et al [65, 66] studied the effects of water vapor and fly ash on the Hg0 removal
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performance of CeO2-modified semi-coke via experimental and theoretical calculation method. Hg0
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removal efficiency dropped by 30% in the presence of 10% water vapor, which was probably owing
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to the formation of Ce-OH groups and the depletion of lattice oxygen. The addition of 0.5 g fly ash
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showed little influence on mercury removal performance. However, the Hg0 removal efficiency
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reduced by only 15% in coexistence of water vapor and fly ash. This indicated that the production
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of Fe-OH groups stemmed from the interaction of H2O and Fe2O3 in the fly ash reduced the
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inhibitive effect of water steam. The effects of water vapor and fly ash on Hg0 removal over
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CeO2-modified semi-coke is presented in Fig. 2. Fly ash slowed down the suppressive impact of
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H2O on Hg0 removal over CeO2-modified semi-coke. Because some lattice oxygen on Fe2O3
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surfaces was converted to highly active Fe-OH groups. The content of Fe-OH group on γ-Fe2O3
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surface augmented faster than that of α-Fe2O3 after steam treatment, contributing to the higher Hg0
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removal performance of γ-Fe2O3 than α-Fe2O3.
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Fig. 2 The promotive mechanism of H2O on Hg0 removal over Fe2O3.
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Petroleum coke is a waste by-product of petroleum refining process with large amounts readily
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available worldwide. Due to its high intrinsic sulfur content, petroleum coke is regarded as an
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attractive raw material for developing carbon-based mercury sorbent. Brominated petroleum cokes
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had been recently employed for Hg0 removal [67, 68]. The bromine loaded on petroleum coke was
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stable up to 200 °C. The Br-modified petroleum coke displayed excellent Hg0 removal efficiency at 9
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100 and 200 °C. The intrinsic sulfur, primarily in the form of thiophene and organic sulfide, could
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raise bromine depositing and increased mercury capture capacity.
193
4. Bio-char
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Biomass, as a renewable resource, has been extensively applied in preparation of
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carbon-based sorbents for catalytic and adsorption reactions due to its ample source, sustainability,
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economy, and environmental benign. Bio-char, as a new kind of mercury sorbent, can be easily
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attained via thermal pyrolysis of diverse terrestrial or marine biomass and biomass wastes, such as
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woody and fibrous plants [69, 70], agricultural waste [71], nut waste [72], seaweed [73] and so
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forth. After devolatilization and reconstruction of carbohydrate polymers, the resultant bio-chars
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with loosely developed pore structures and highly active surface oxygen functional groups possess
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excellent prospect as mercury sorbents [74].
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4.1 Agricultural waste-derived bio-char
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Lots of agricultural waste, such as rice straw, wheat straw, maize straw etc., can be used for
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bio-char preparation. Cu-Ce modified bio-chars derived from rice straw demonstrated good Hg0
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removal performance [76]. The optimal Cu/Ce molar ratio, calcination temperature, and reaction
206
temperature were 1:5, 260 °C, and 150 °C, correspondingly. Yang et al. [78] synthesized a
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magnetic Co-Fe impregnated porous carbon stemmed from rice straw by microwave and steam
208
activation [78]. Ultrasound-assisted impregnation improved the dispersion of Co3O4 and Fe3O4 on
209
sorbent surface. While the activation of microwave and steam greatly improved the pore structures.
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The surface chemisorbed oxygen and the lattice oxygen stemmed from Co3O4 and Fe3O4 involved
211
in Hg0 removal process. Besides, Co-Fe modified porous carbon showed good regeneration
212
performance. The plausible mechanism of Hg0 capture on Co-Fe loaded porous carbon is illustrated
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in Fig. 3. The adsorbed Hg0 was oxidized into Hg2+ by high-valence Co3+ and Fe3+ ions. The
214
low-valence Co2+ and Fe2+ ions could be replenished by the oxygen from gas stream.
215 216
Fig. 3 The mechanism of Hg0 capture by Co-Fe doped porous carbon.
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K2FeO4-modified bio-chars derived from wheat straw were developed for Hg0 removal [79].
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K2FeO4 modification improved the pore structures and introduced new active sites, greatly
219
promoting Hg0 removal performance. Hg0 removal efficiency reduced with rising Hg0 inlet content.
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NO facilitated Hg0 removal, because it could oxidize Hg0 into Hg(NO3)2. SO2 greatly decreased Hg0
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removal efficiency because of the competitive adsorption between SO2 and Hg0. Yang et al. [80]
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used a wheat straw derived bio-char modified with Mn-Ce oxides to remove Hg0 at low
223
temperature. NO and O2 improved Hg0 removal performance. Low content of steam and SO2
224
enhanced Hg0 removal, but high content of steam and SO2 restrained Hg0 removal. Magnetic Fe-Cu
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doped bio-chars stemmed from wheat straw were employed for capturing Hg0 from flue gas [81].
226
The Fe-Cu active species, chemisorbed oxygen, and lattice oxygen on sorbent surface were
227
profitable for Hg0 removal.
228
Corn stalk derived bio-chars were treated with dielectric barrier discharge plasma to promote
229
its Hg0 adsorption capacity [82]. After plasma treatment, the surface area and pore volume reduced
11
230
subtly. While the oxygen-containing functional groups, especially C=O groups, augmented on
231
sorbent surface. The bio-chars with plasma treatment showed higher Hg0 removal efficiency than
232
that of untreated ones. The Hg0 adsorption process was probably dominated by chemisorption,
233
attributed to the highly active carbonyl and ester functional groups. Gao et al. [83] developed a
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maize straw derived activated carbon modified with Co-Ce to simultaneously remove NO and Hg0.
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There was a cooperative effect between Co3O4 and CeO2, leading to production of more Co3+ and
236
Ce3+ cations to induce more anionic defects and form more active oxygen and oxygen vacancies.
237
NO reduction was primarily governed by Langmuir-Hinshlwood mechanism, while Hg0 oxidation
238
related to Mars-Masson mechanism. Shan et al. [84] developed a magnetic Ce-Fe modified
239
bio-char stemmed from maize straw for elemental mercury abatement. During Hg0 removal
240
processes, Ce4+ and Fe3+ ions were reduced to Ce3+ and Fe2+ ions, respectively. The chemisorbed
241
oxygen species were significantly depleted as well.
242
Ammonium halide-modified cotton straw derived bio-chars were adopted for Hg0 removal
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[85]. Increasing temperature could increase the mercury adsorption capacity of NH4Br and NH4I
244
modified bio-chars, whereas, high temperature would decrease the mercury adsorption capacity of
245
NH4Cl modified bio-chars. The C-X groups were identified as the dominant adsorption sites for
246
Hg0. Magnetic Mn-Fe modified cotton straw derived bio-chars performed well with respect to
247
elemental mercury abatement [86]. Microwave activation was profitable for the development of
248
pore structures. And ultrasound treatment facilitated the dispersion of Mn and Fe active
249
components.
250
To further improve the Hg0 removal performance of bio-chars. Non-thermal plasma method
251
had been adopted to introduce chlorine active sites on bio-char surface. HCl plasma activation
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252
increased the chlorine active sites on the surface of sorghum straw derived bio-chars, contributing
253
to the significant rise in Hg0 removal efficiency [87]. X-ray absorption near edge structure
254
(XANES) analysis disclosed that the adsorbed mercury on HCl-modified bio-chars was primarily
255
presented in the form of Hg+. Hg0 vapor reacting with chlorinated active sites via electron-transfer
256
yielded Hg2Cl2. A lot of biomasses, i.e., rice straw, tobacco straw, corn straw, wheat straw, millet
257
straw, and black bean straw had been used for preparing bio-chars which were then activated with
258
Cl2 non-plasma approach [88].The number of C-Cl groups was increased after Cl2 plasma
259
treatment. The produced C-Cl groups served as active sites which enhanced Hg0 removal process.
260
The six biomasses derived bio-chars were also activated by H2S plasma, leading to the
261
remarkable increase of sulfur-containing and carboxyl groups on bio-char surface [89]. The
262
bio-chars after H2S plasma modification presented better Hg0 removal ability than unmodified ones.
263
C-S and carboxyl were recognized as the dominant functional groups producing HgS and HgO,
264
respectively. The process of Hg0 capture by H2S plasma treated bio-chars is illustrated in Fig. 4.
265
Active C-S bonds could be formed on bio-char surface after H2S plasma treatment. Active sulfur
266
species was released from the C-S bonds at high temperature and further oxidized Hg0 into HgS.
267
Besides, Hg0 could also be oxidized into HgO by the oxygen in carboxyl groups.
268 269 270
Fig. 4 Hg0 adsorption on H2S plasma activated bio-chars. A sequence of Co-doped MnOx/biomass activated carbons were developed for simultaneously
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removing NO and Hg0 from flue gas [90]. Co addition increased the surface active oxygen
272
components and Mn4+ content of MnOx/biomass activated carbons. The enhancement of redox
273
ability and the strength of surface acidic sites restrained the crystallization of MnOx, possibly
274
contributing to the improvement of mercury removal performance and resistance to SO2 and H2O.
275
Xu et al. [91] prepared magnetic chlorinated bio-chars by one-step pyrolysis of Fe(NO3)3-laden
276
wood and polyvinyl chloride mixture. The Fe-Cl co-modified bio-chars displayed far better Hg0
277
removal performance than Cl-modified bio-chars. The produced Fe3O4, C-Cl bonds, and C=O
278
bonds were identified as the major active sites for Hg0 removal. The synthesis route and Hg0
279
capture process of magnetic Fe-Cl co-modified bio-chars are depicted in Fig. 5. Magnetic Fe-Cl
280
co-modified bio-chars were prepared by prolysis of Fe-laden wood and polyvinyl chloride (PVC)
281
mixture. Hg0 could be oxidized into Hg2+ by Fe3O4, C-Cl, and C=O groups.
282 283 284
Fig. 5 Synthesis and performance of magnetic Fe-Cl co-modified bio-chars. 4.2 Seaweed-derived biochar
285
The bio-chars stemmed from agricultural wastes cannot be produced on a large scale owing to
286
the geographical restriction of crop planting and limited arable lands [92]. However, ocean owns
287
huge amounts of seaweed biomass resources. The development and utilization of the seaweed
288
biomass resources, such as Sargassum, Enteromorpha, etc., could be a feasible pathway to tackle
14
289
these issues [93, 94].
290
NH4Cl- and NH4Br-modified Sargassum chars were employed for elemental mercury
291
abatement [95, 96]. Low contents of SO2 and H2O favored Hg0 removal, whereas, high contents of
292
SO2 and H2O restrained Hg0 adsorption. C-Br, C-Cl, and C=O covalent functional groups were the
293
predominant active sites. The Hg0 capture on NH4Cl- and NH4Br-modified Sargassum chars both
294
subjected to pseudo-second-order kinetic model, suggesting that Hg0 removal was controlled by
295
chemisorption process. NH4Cl- and NH4Br-modified Enteromorpha chars were also used to remove
296
Hg0 from flue gas [97]. Chlorine and bromine impregnation both promoted Hg0 adsorption. The
297
Br-modified Enteromorpha chars performed better than Cl-modified ones. The Hg0 adsorption on
298
Cl- and Br-modified Enteromorpha chars was endothermic process.
299
To avoid the release of harmful ammonia during bio-char modification process, potassium
300
halide was adopted to modify Enteromorpha chars and Sargassum chars for elemental mercury
301
abatement [98]. The Hg0 removal performances of KI-modified bio-chars were superior to KCl- and
302
KBr-modified ones. The C-I covalent groups and chemisorbed oxygen and/or weakly bonded
303
oxygen species were the dominant chemisorption sites. The application scenarios of seaweed
304
biomass are presented in Fig. 6. Bio-chars and bio-oil could be simultaneously attained by
305
high-temperature pyrolysis of seaweeds. The potassium halide-modified bio-chars were then used to
306
remove Hg0.
15
307 308
Fig. 6 The utilization of seaweed biomass for producing bio-oil and bio-chars.
309
Activated carbon was attained by pyrolysis of Sargassum and Enteromorpha associated with
310
ZnCl2 activation [99]. The Hg0 removal performances of the seaweed-derived activated carbons
311
were much better than those of the seaweed-derived chars. The optimal activation temperature was
312
800 °C. The Hg0 removal process was governed by exterior mass transfer at 80 °C and controlled
313
by chemisorption at 120 and 160 °C. The Hg0 removal process of the seaweed-derived activated
314
carbon was a combination of physisorption and chemisorption, attributed to the large specific
315
surface area and the C-Cl functional groups and active oxygen species, respectively. Though
316
seaweed-derived bio-chars have been considered as good candidates for mercury removal, the
317
harvesting cost of seaweed and large consumption of thermal energy for wet seaweed drying are the
318
major defects.
319
5. Low-dimensional carbon
320
Low dimensional carbons, as emerging carbon materials, are those own at least one physical
321
border small enough to confine electrons. This quantum confinement effect reduces the
322
dimensionality of the materials, imparting them distinct and novel properties that are not presented
323
in their bulk forms [100]. The low-dimensional carbons have also been applied for Hg0 removal in
324
recent years.
325
5.1 Graphene and graphene oxide 16
326
Graphene, known as a new member of two-dimensional carbon-based nanomaterials with a
327
single layer of sp2-hybrid carbon atoms packed into a benzenering structure, has recently aroused
328
widespread attention due to its exceptional electrical, mechanical, and thermal property [101, 102].
329
Graphene oxide possesses ample oxygen-containing functional groups, such as hydroxyl, epoxy and
330
carboxyl groups [103], which are favorable for adsorption and oxidation reactions. Therefore,
331
graphene and its derivates have been applied in many fields due to their large specific surface area,
332
fast electron transferring speed, and good mechanical strength [104].
333
Xu et al. [105, 106] prepared MnOx/graphene and Ag/graphene composites for Hg0 capture
334
at low temperature. Graphene seemed to be a perfect carrier for MnOx particles. It could be readily
335
deposited on graphene surface via hydrothermal process. Graphene also acted as electron transfer
336
channels in Hg0 oxidation reaction. Graphene facilitated the electrical conductivity of MnOx, which
337
was profitable for Hg0 oxidation reaction. Besides, MnOx/graphene and Ag/graphene both showed
338
splendid regenerative ability. Mercury as a resource could be recycled by using Ag/grapheme
339
sorbent via a facile thermal regeneration route. Though silver is a precious metal, its dosage is much
340
less than that of transition-metal oxide. Beside, the Ag-deposited graphene can be recycled after
341
heating treatment, making silver a promising modifying reagent for graphene. The synthesis route
342
of Ag/graphene and its application in Hg0 capture from flue gas is presented in Fig. 7. Graphene
343
was first synthesized using Hummers method. AgNO3 and N2H4 were then mixed together with the
344
graphene and subsequently dried and calcinated under nitrogen stream to yield Ag/graphene. The
345
Hg0 capture performance was evaluated in a horizontal a fix-bed reactor.
17
346 347
Fig. 7 The synthesis process of Ag/graphene and its application for Hg0 removal.
348
Graphene was employed to enhance the Hg0 removal performance of Mn-Ce binary metal
349
oxides [107]. The high valances of Mn4+ and Mn3+ favored Hg0 oxidation. Ceria offered abundant
350
oxygen for mercury oxidation. Graphene promoted Hg0 oxidation and adsorption process via
351
providing more reaction space and facilitating electron transfer. The field emission scanning
352
electron microscopy images of graphene oxide, MnOx@graphene oxide, and Mn-Ce@graphene
353
oxide are shown in Fig. 8. The pristine graphene oxide exhibited typical nanosheet structures. For
354
MnOx@graphene oxide, MnOx nanoparticles were evenly dispersed on the surface of graphene
355
oxide. Mn-Ce@graphene oxide presented a three-dimensional morphology with some graphene
356
oxide being covered by MnOx and CeOx grains.
357 18
358
Fig. 8 Field emission scanning electron microscopy pictures of (a) and (b) graphene oxide, (c)
359
MnOx@graphene oxide, and (d) Mn-Ce@graphene oxide.
360
Ag nanoparticles were deposited on graphene oxide for Hg0 abatement [108]. The
361
Ag/graphene oxide composite could efficiently capture Hg0 from flue gas up to 150-200 °C,
362
plausibly owing to the amalgamation of Hg0 on Ag nanoparticles. An et al. [109] reported that
363
loading Mn-Fe-Ce mixed oxides on graphene oxide could effectively remove Hg0 from flue gas at
364
170-250 °C. The Mn-Fe-Ce active components were readily dispersed on graphene surface due to
365
its large specific surface area and good mechanical property. A magnetic Ag-Fe3O4@graphene
366
oxide ternary composite was synthesized for gaseous Hg0 capture from coal-fired flue gas [110].
367
The ternary composite performed better than pristine graphene oxide and Fe3O4@graphene oxide.
368
The Hg0 was captured via Ag-Hg amalgam mechanism. The magnetic ternary composite was
369
reusable and could be possibly separated from fly ashes for multicycle utilization.
370
Apart from experimental studies, theoretical calculation method has also been applied to
371
explore the potential of graphene towards Hg0 capture and the mechanism of Hg0 adsorption on
372
graphene. Meeprasert et al. [111] studied the reactivity of single-vacancy defective graphene and
373
defective graphene-supported Pdn and Agn (n = 1, 13) towards Hg0 adsorption by using density
374
functional theory calculation method. Pdn showed higher binding ability with the defective site of
375
graphene than Agn. Metal nanocluster bonded stronger with defective graphene than single metal
376
atom. Jungsuttiwong et al. [112] studied the mechanism of Hg0 adsorption on transition-metal
377
decorated boron-doped graphene with periodic density functional theory. Pd4 type A structure
378
exhibited the highest Hg0 adsorption performance. The interaction of Hg-5d orbital and Pd-4d,
379
Pt-5d orbital contributed to its high Hg0 adsorption ability. The top view of the optimized structure
19
380
of B-doped graphene surface is presented in Fig. 9. The optimized B-doped graphene sheet
381
encompassed 12 B atoms (in red color) and 60 C atoms (in gray color). The optimal B-doped
382
graphene surface was then prepared for transition-metal atom and cluster deposition.
383 384
Fig. 9 Top view of the optimized structure of B-doped graphene in a 6 × 6 unit cells.
385
Density functional theory calculations were performed to investigate the adsorption processes
386
of mercury and arsenic on Pdn (n=1-6) decorated pyridine-like N-doped graphene [113]. The
387
vacancy site was confirmed as the most favorable adsorption site for Pd atom. The Pd atoms or
388
clusters could promote the reactivity of N-doped graphene with respect to Hg and AsH3 adsorption.
389
The capture ability of Hg on Pdn/N-doped graphene was linked to the d-band center of Pdn. The
390
closer the d-band center of Pdn to the Fermi level was, the higher adsorption strength of Hg on
391
Pdn/N-doped graphene was.
392
The adsorption processes of Hg0 on perfect, defective, and Al-doped graphene were studied
393
based on density functional theory [114]. The adsorption energies of Hg0 on perfect and defective
394
graphene were -0.220 eV and -0.342 eV, respectively, which were physisorption processes.
395
Whereas, the adsorption energy of Hg0 on Al-doped graphene was -0.570 eV, which was a
396
chemisorption process. The adsorption energy increased with increasing Al-doped vacancy sites.
397
However, the incremental Al atoms doped on a single vacancy site would reduce the adsorption
20
398
energy, which was unfavorable for Hg0 adsorption.
399
5.2 Carbon nanotube and nanofiber
400
Carbon nanotubes and nanofibers are new types of one-dimensional nanomaterials. The
401
carbon nanotubes possess perfect hexagonal connected structures, distinct thermal, electrical and
402
mechanical characteristics [115]. The carbon nanofiber features low density, large length-diameter
403
ratio, high strength, good electrical property and corrosion resistance. Furthermore, the oxygen
404
functional groups can be easily produced on the surface of carbon nanotubes and nanofibers via
405
chemical modification [116], which is conducive to Hg0 removal.
406
Mn-Mo oxides were loaded on carbon nanotubes for oxidation removal of Hg0 at low
407
temperature [117]. Mn-modified carbon nanotube displayed high Hg0 oxidation ability at 150-250
408
℃. However, it nearly lost Hg0 oxidation ability in existence of 500 ppm SO2 due to the generation
409
of MnSO4. In contrast, SO2 promoted the Hg0 oxidation ability of Mn-Mo doped carbon nanotube.
410
The probable reason was that Mo addition could facilitate the conversion of SO2 to SO3, which was
411
profitable for Hg0 oxidation. Mo species could also protect MnO2 from SO2 poisoning.
412
Fe-Ce decorated multi-walled carbon nanotube was also used for simultaneous removal of
413
Hg0 and NO from flue gas [118]. The iron-cerium hybrid oxides loaded both inside and outside of
414
the multi-walled carbon nanotube in evenly dispersion form with sizes of 3-5 nm. Some cerium
415
presented in the form of fluorite-like crystal ceria, others entered into the spinel structure of
416
γ-Fe2O3, resulting in the distortion of the γ-Fe2O3 lattice. The amounts of chemisorbed oxygen
417
species and the oxidation activities of catalysts increased remarkably after cerium addition,
418
contributing to the outstanding Hg0 and NO removal performance.
419
Dimethyl sulfoxide was adopted to modify carbon nanofibers for gas-phase Hg0 capture
21
420
[119]. Though sulfur modification reduced the surface areas and pore volumes of carbon
421
nanofibers, mercury uptake capacities augmented as compared to unmodified ones. The sulfur
422
atoms were incorporated into carbon matrix in the form of sulfides and sulfates. The sulfide groups
423
performed more effectively than sulfate groups towards Hg0 removal. Because the lone pair
424
electrons of sulfide groups acted as active sites for sulfur interacting with mercury, or at least as a
425
point of initial attachment. The micro-morphologies of pristine and sulfur-treated carbon nanofibers
426
are shown in Fig. 10. The carbonaceous species were coated on nonwoven fiber glass with diameter
427
of 5-7 μm. No sulfur clusters were observed on the surface of sulfur-treated carbon nanofibers,
428
confirming that sulfur atoms might be built-in with carbon matrix.
429 430
Fig. 10 The scanning electron microscope images of (A) pristine and (B) sulfur-treated carbon
431
nanofibers.
432
The probable mechanism of Hg0 capture by sulfur-treated carbon nanofibers is shown in Fig. 11.
433
First, Hg0 was oxidized into Hg(II) and formed a double bond with S atom via donating two pairs of
434
shared electrons. Then, one electron transferred from Hg=S double bond to C-S single bond,
435
producing active Hg and C species with one electron. Finally, the reactive electrons of Hg and C
436
species generated a single bond. The original C-S bond broke and yielded a lone pair of electrons.
22
437 438
Fig. 11 The mechanism of Hg0 adsorption on sulfur-treated carbon nanofibers.
439
Magnetic Fe-Mn oxide loaded carbon nanofibers were synthesized via one-step
440
solvothermal approach for Hg0 removal [120]. The Hg0 removal performance greatly augmented
441
with incremental Mn doping amount into Fe3O4 spinel structures. Carbon nanofiber addition
442
improved the dispersion of Fe-Mn oxide grains and promoted the electron transfer mobility, which
443
favored Hg0 removal. Mn cations and lattice or chemisorbed oxygen were regarded as active sites
444
for Hg0 oxidation. Mn-Ce oxides were supported on carbon nanofibers for Hg0 abatement [121].
445
Mn-Ce oxides were highly dispersed on carbon nanofibers and offered sufficient active components
446
for Hg0 oxidation, such as active oxygen and Mn4+ ions. The carbon nanofiber framework provided
447
channels for electron transfer during Hg0 oxidation process.
448
5.3 Carbon sphere
449
Carbon sphere, as a zero-dimensional carbon material, displays numerous advantages over
450
powder or granular activated carbon for catalyst support and adsorption process, probably owing to
451
its high surface area, excellent mobility, high compressive strength, low pressure drop, and potential
23
452
application in large-scale fluidized bed [122, 123].
453
Hierarchical α-MnO2/carbon sphere composite was fabricated via hydrothermal route for
454
Hg0 oxidation and adsorption [124]. Carbon spheres served as the core on which α-MnO2 nanorods
455
grew. The α-MnO2/carbon sphere composite performed stably with Hg0 removal efficiency of
456
>99% over 600 min on stream. Besides, it had better SO2 resistance than unsupported α-MnO2. This
457
three-dimensional α-MnO2/carbon sphere composite composed of zero-dimensional carbon sphere
458
and one-dimensional α-MnO2 was appealing for gas purification.
459
Resin-based carbon spheres were synthesized by suspension polymerization of alkyl phenol
460
and formaldehyde and steam activation in combination with surface modification by heat treatment
461
[125]. The pure carbon spheres attained via oxidation modification at 300 °C performed well,
462
probably attributed to the sufficient oxygen functional groups of C=O and C(O)-O-C. These oxygen
463
functional groups acted as strong oxidizer and promoted electron transfer for converting Hg0 to
464
Hg2+ during Hg0 chemisorption process.
465
Zhang et al. [126, 127] further modified the resin-based carbon spheres with CuO or CeO2
466
to improve its Hg0 removal ability. CuO enhanced the redox ability of the carbon sphere and was
467
profitable to activate its active species, which appreciably improved Hg0 removal performance.
468
CeO2 greatly enhanced the Hg0 removal ability of the carbon sphere through forming active species,
469
such as C=O or C-O, and lattice oxygen via Ce4+/Ce3+ redox couple for oxidizing Hg0 into HgO.
470
The micro-morphology of resin-based carbon sphere is displayed in Fig. 12. The carbon sphere
471
exhibited a relatively smooth surface with a large specific surface area of >1000 m2/g. Few pores
472
and pitted morphology were formed on the surface of the carbon sphere after steam activation.
24
473 474
Fig. 12 The scanning electron microscope image of resin-based carbon sphere.
475
The proposed mechanism for Hg0 capture on CuO-modified carbon sphere is displayed in Fig. 13.
476
Hg0 vapor was first adhered on the surface or in the pore channels of the carbon sphere. Then, it
477
was oxidized by the active components of the carbon sphere, such as C=O or C-O. Furthermore,
478
CuO would promote the activation of the active components and could also oxidize the adsorbed
479
Hg0 by itself.
480
481 482 483
Fig. 13 The mechanism of Hg0 adsorption on CuO-modified carbon sphere. 6. Carbon composite and polymer
25
484
Incorporating heteroatoms into carbon matrix can alter the electronic structures of
485
carbonaceous materials [128], which may lead to improvement in catalytic and adsorption ability.
486
Carbon bonded with metals could form metal-organic framework, which shows great potential in
487
gas separation. Carbon bonded nitrogen could produce graphitic carbon nitride, which is an
488
emerging carbon-based polymers. The metal-organic framework and graphitic carbon nitride have
489
recently been employed for Hg0 removal as well, which has become a research hotspot.
490
6.1 Metal-organic framework
491
Metal-organic frameworks, as a new class of porous materials or porous coordination
492
polymers assembled by metal ions and polyfunctional organic ligands, exhibit low density, high
493
porosity and apparent surface area, controllable pore size, well-defined structure, and chemical
494
tunability [129-132]. Since Yaghi and coworkers [133, 134] first proposed crystalline metal
495
organic frameworks, they have attracted great attention and have been applied in many fields, such
496
as hydrogen storage [135, 136], gas adsorption and separation [137, 138], catalytic reactions [139,
497
140], and environmental remediation [141, 142]. Recently, elemental mercury capture by using
498
metal-organic frameworks has gained increasing research interest due to the maturity of
499
metal-organic framework synthesis methods and the increasingly stringent regulations for mercury
500
emissions.
501
Liu et al. [143] first studied the adsorption potential of metal-organic frameworks towards
502
mercury species, i.e., Hg0, HgCl2, HgO, and HgS, by theoretical calculations based on density
503
functional theory method. The Hg0 was stably physi-sorbed on the unsaturated metal centers of
504
Mg-based metal-organic framework. The Cl endings of HgCl2 multi-interacted with two neighbored
505
Mg ions simultaneously, leading to strong adsorption strength. HgO and HgS were chemisorbed on
26
506
Mg-based metal-organic framework. Therefore, metal-organic frameworks were theoretically
507
predicted to be promising for effective removing mercury species from coal-fired flue gas.
508
Later, phenyl bromine-appended metal-organic frameworks were employed for Hg0 removal
509
[144]. Phenyl bromine was the primary chemisorption site for Hg0 capture. The optimal Br-based
510
metal-organic framework performed much better than un-functionalized metal-organic framework
511
and Br-impregnated activated carbon. The Br-based metal-organic framework showed enhanced
512
Hg0 removal efficiency in the presence of SO2, whereas steam suppressed its Hg0 removal
513
performance. The Br-based metal-organic framework showed high bromine stability during Hg0
514
adsorption, which could avoid possible bromine pollution issue often along with Br-modified
515
sorbents.
516
Mn-Ce modified metal-organic framework was also used for Hg0 and NO removal [145]. It
517
performed better than conventional Mn-Ce loaded ZrO2, especially at low temperature. The
518
metal-organic framework promoted the dispersion of active components, improved Hg0 adsorption
519
and enhanced oxygen utilization, resulting in a desirable catalytic activity. Zhao et al. [146]
520
investigated the combined effect of Ag and Zr-based metal-organic framework with respect to Hg0
521
removal. Ag addition promoted the redox activity of Zr-based metal-organic framework. Ag and
522
Zr-based metal-organic framework presented a significant cooperative effect towards Hg0 removal.
523
The plausible reaction pathways for Hg0 removal by Ag-modified Zr-based metal-organic
524
framework is illustrated in Fig. 14. At low temperature, Hg0 vapor was predominantly captured via
525
generating an Ag-Hg amalgam and channel adsorption. At high temperature, Ag transferred an
526
electron to the oxygen of C=O group to form active oxygen which then attracted an electron from
527
Hg0 through Ag. Besides, the formed active Zr combined with Hg0, which could be captured via
27
528
channel adsorption as well.
529 530
Fig. 14 The reaction pathways of Hg0 removal by Ag-modified Zr-based metal-organic framework.
531
A Cu-based metal-organic framework was adopted for Hg0 removal from sintering gas [147].
532
The Cu-based metal-organic framework showed limited Hg0 removal ability without HCl. Presence
533
of 15 ppm HCl could greatly enhanced its Hg0 removal efficiency. SO2 inhibited Hg0 removal,
534
whereas NO enhanced Hg0 adsorption. Furthermore, Cu-based metal-organic framework exhibited
535
good water-resistance. The mechanism Hg0 removal by Cu-based metal-organic framework is
536
depicted in Fig. 15. Without HCl in sintering gas, Hg0 was removed primarily by active oxygen via
537
forming HgO. With HCl in sintering gas, HCl was adsorbed on Cu-based metal-organic framework
538
to produce intermediates of CuCl or CuCl2. Hg0 was first oxidized into Hg2+ by chemisorbed
539
oxygen species. Then, the produced Hg2+ reacted with CuCl or CuCl2 to generate HgCl2.
540
Furthermore, Cl- ions may be activated by oxygen to produce active chorine species which could
541
oxidize Hg0 into HgCl2.
28
542 543
Fig. 15 The mechanism of Hg0 removal by Cu-based metal-organic framework.
544
It was reported that Cr-based metal-organic framework performed better than Cu-based and
545
Zr-based metal-organic framework [148]. Hg0 removal efficiency augmented with the increasing
546
reaction temperature and oxygen content. The open metal site of Cr-based metal-organic framework
547
was the key factor for Hg0 removal. Hg0 was first adsorbed on Cr-based metal-organic framework
548
and then oxidized into Hg2+ by the open metal site Cr3+. The yielding Hg2+ subsequently reacted
549
with chemisorbed oxygen to produce HgO. While the reduced open metal site Cr2+ was reoxidized
550
into Cr3+ by surface active oxygen. However, high-valence chromium is harmful to human health,
551
which might limit its further application.
552
Zhou et al. [149] loaded α-MnO2 onto Al-based metal-organic framework for Hg0 removal.
553
Al-based metal-organic framework could expose more active sites of α-MnO2, contributing to the
554
enhancement in the Hg0 oxidation ability of α-MnO2. A Se-functionalized metal-organic framework
555
was synthesized for Hg0 removal [150]. The Se-based metal-organic framework displayed a
556
distinguished mercury adsorption capacity of 148.19 mg/g which was about 154 to 705 times bigger
557
than that of commercial activated carbons. Besides, its prominent mercury adsorption stability could
558
still retain under simulated flue gas atmosphere. The gas-phase Hg0 was oxidized into stable and
559
water-insoluble HgSe, ensuring the minimal re-emission or even sequestration of mercury. 29
560
However, the scarcity and toxicity of selenium might be an obstruction for its practical application.
561
6.3 Graphitic carbon nitride
562
Graphitic carbon nitride (g-C3N4), the most stable allotrope of polymeric carbon nitride, has
563
attracted increasing attention due to the facile synthesis route, abundant sources, high thermal and
564
chemical stability, environmentally benign and good biocompatibility, and distinctive electronic
565
structure [151-154]. These unique properties allow for its diverse applications, such as
566
photocatalytic hydrogen evolution [155], wastewater decontamination [156], nitric oxide removal
567
[157], and carbon dioxide reduction [158]. Recently, Liu et al. [159] first explored the potential of
568
g-C3N4 for Hg0 adsorption. They found that g-C3N4 exhibited strong affinity with Hg0. Precursors
569
had a big impact on Hg0 removal performance. The g-C3N4 stemmed from urea high-temperature
570
polymerization displayed a striking Hg0 capture ability with Hg0 removal efficiency of ~84%,
571
which was significantly higher than those of dicyandiamide- and melamine-derived g-C3N4. The
572
probable reason was that the specific surface area of the urea-derived g-C3N4 was much bigger than
573
those of the dicyandiamide- and melamine-derived g-C3N4.
574
CuO/g-C3N4 nanocomposites were prepared via incipient-wetness impregnation method for
575
elemental mercury abatement [160]. Pristine g-C3N4 was attained via a two-step calcinating
576
approach. g-C3N4 displayed good Hg0 adsorption performance at 40-200 °C. CuO decoration
577
greatly enhanced the Hg0 removal ability of g-C3N4 owing to the close interaction of CuO and
578
g-C3N4. Liu et al. [161] fabricated a porous g-C3N4 via a facile two-step thermal etching oxidation
579
method for Hg0 removal. The porous g-C3N4 also displayed good reactivity towards Hg0 adsorption
580
at 40-200 °C. CuO decoration efficiently activated g-C3N4, imparting it enhanced Hg0 oxidation
581
ability due to the Mott-Schottky effect at the interface of CuO and g-C3N4.
30
582
It is well established that g-C3N4 nanosheet owns big surface area for exposing plentiful
583
active sites and short bulk diffusion length for promoting electron transfer, which are conducive to
584
adsorption and catalytic reactions [162, 163]. A two-dimensional g-C3N4 nanosheet was synthesized
585
via thermal exfoliation of bulk g-C3N4 [164, 165]. The g-C3N4 nanosheet performed well with
586
respect to Hg0 removal at 60-240 °C. The maximal Hg0 removal efficiency of ~65.8% was reached
587
at 150 °C due to the two-dimensional planar structure and big specific surface area of g-C3N4
588
nanosheet. The transmission electron microscopy photo of g-C3N4 nanosheet is shown in Fig. 16.
589
The pristine g-C3N4 nanosheet displayed ultrathin sheet-like morphology with thickness of ~1-10
590
nm and lateral size of ~1-3 µm. The specific surface area of the g-C3N4 nanosheet was ~109 m2/g.
591 592
Fig. 16 The transmission electron microscopy image of g-C3N4 nanosheet.
593
MnO2 and Co3O4 decoration significantly enhanced the Hg0 removal performance of the
594
g-C3N4 nanosheet. The plausible reason was attributed to the excellent redox abilities of MnO2 and
595
Co3O4 and the enhanced electron mobility at the interface of MnO2 or Co3O4 and g-C3N4.
596
MnO2-decorated g-C3N4 nanosheet displayed Hg0 removal efficiency all above 91% within 90-240
597
°C. Co3O4-modified g-C3N4 nanosheet presented excellent Hg0 capture ability with Hg0 removal
598
efficiency of ~100% within 120-240 °C. However, NO and SO2 significantly inhibited the Hg0
599
removal performance of the Co3O4-modified g-C3N4 nanosheet, probably due to the competitive 31
600
adsorption and side reactions. The mechanism of Hg0 removal over MnO2-modified g-C3N4
601
nanosheet is depicted in Fig. 17. The gas-phase Hg0 was oxidized into HgO by surface active
602
oxygen (Oad) and lattice oxygen ([O]) of MnO2 which was reduced to Mn2O3. Gaseous O2
603
replenished the depleted chemisorbed oxygen and lattice oxygen and simultaneously oxidized
604
Mn2O3 into MnO2 to refresh the active component for Hg0 oxidation.
605 606
Fig. 17 The process of Hg0 oxidation by MnO2-loaded g-C3N4 nanosheet.
607
In addition, Liu et al. [166] first employed CuCl2-loaded carbon aerogels for elemental
608
mercury removal at low temperature. It displayed very stable Hg0 removal performance with
609
~100% Hg0 removal efficiency over 600 min on stream. To further lower down the capital cost of
610
carbon aerogel, a seaweed-templated pathway was developed for controllable synthesis of
611
SnO2-loaded carbon aerogels to simultaneously remove Hg0 and H2S [167]. The carbon aerogels
612
possess distinct three-dimensional network structures. The nanoconfinement of carbon nanoshells
613
could prevent the growth and agglomeration of SnO2 nanoparticles during regeneration process,
614
which favored removal of Hg0 and H2S [168-170]. The three-dimensional interconnected macro-
615
and meso-pores of carbon aerogels was conducive to Hg0 and H2S removal at high space velocities.
32
616
Carbon aerogel might also be a potential carbon-based sorbent for Hg0 removal provided the capital
617
cost is reduced and synthesis process is simplified. In addition, some practical industrial gas streams
618
are extremely complex, and often simultaneously contain multiple gas components such as H2O,
619
NOx, HCl, H2S, SO2, CO, SO3, VOCs, etc [171-180]. Thus much more work should be conducted
620
to further improve the stability of these carbon-based adsorbents in the presence of H2O, NOx, HCl,
621
H2S, SO2, CO, SO3, VOCs, etc., and reveal the effects of these gas components on Hg0 removal.
622
7. Conclusions and prospects
623
Atmospheric mercury pollution has become a global concern mainly due to the large
624
consumption of fossil fuels and gold mining. The primary challenge for reducing elemental mercury
625
from gas streams is to search for environmentally benign, inexpensive, regenerable, and efficient
626
mercury sorbents with good resistance to NO, SO2, and H2O. Carbon-based materials are deemed to
627
be appealing candidates for removing Hg0 from gas streams at low temperature. This review
628
provided the state-of-the-art of carbon-based sorbents for elemental mercury abatement in the view
629
point of material and chemistry. To date, massive carbon materials have been employed for Hg0
630
capture. The advantages and disadvantages of versatile carbon-based materials towards elemental
631
mercury removal are summarized as follows.
632
Activated carbon is the only commercialized mercury sorbent due to its wealthy pore
633
structure and sufficient surface oxygen functional groups. Activated carbon injection technology
634
has been widely applied in coal-fired power plants. However, the high operation cost and
635
detrimental effect on fly ash utilization hampered its industrial application. Activated coke,
636
including semi-coke and petroleum coke, could be alternatives to the activated carbon because of its
637
higher mechanical strength, better regenerability, and lower capital cost. Ongoing and future efforts
33
638
should pay more attention on how to improve its reusability and efficiency. Combing magnetic
639
metal oxides with activated coke is a feasible pathway to tackle this issue.
640
Bio-chars, obtained from direct pyrolysis of diverse terrestrial or marine biomass and biomass
641
wastes at high temperature, are regarded as sustainable and inexpensive mercury sorbents. So far,
642
bio-chars have been extensively investigated for elemental mercury removal owing to their
643
sustainability and sufficient sources. However, virgin bio-chars display fairly low surface area and
644
poor activity towards Hg0 adsorption. In situ activation can greatly improve the porosity and surface
645
area of the bio-chars, and thereby strengthening Hg0 removal performance. Besides, appropriate
646
modification methods, e.g., green, efficient, and inexpensive, associating with high removing
647
efficiency and less contamination to the environment, plays a pivotal role in the large-scale
648
application of bio-chars.
649
Low-dimensional carbons own good electronic conductivity and excellent electron transfer
650
mobility, making them good mercury sorbents after loading with active components. However, the
651
synthesis routes for most low-dimensional carbons, particularly graphene, are time consuming and
652
energy consumption, leading to high capital costs of the low-dimensional carbons. Furthermore, the
653
low activities of pristine low-dimensional carbons restrained their practical utilizations.
654
Metal-organic frameworks are characterized by tunable chemical properties and porous structures
655
through altering their carbonaceous ligands. Some research works showed that metal and halogen
656
modified metal-organic frameworks displayed good Hg0 removal performance. Nevertheless, the
657
high cost and sensitivity towards steam and acidic and basic gases restricted their large-scale
658
application. Thus, the development of low-dimensional carbon and metal-organic framework
659
sorbents highly depend on the progress in material science and engineering. The development of
34
660
new synthetic processes with low cost and simple operation and recyclable characteristics of
661
sorbents are the key factors in the further development of low-dimensional carbon and
662
metal-organic framework mercury sorbents.
663
Graphitic carbon nitride is a new kind of carbon-based sorbent for elemental mercury
664
abatement from coal-derived flue gas. Recent experimental studies found that g-C3N4 performed
665
effectively towards Hg0 adsorption at low temperature. The strong affinity of g-C3N4 with Hg0 is
666
plausibly attributed to its unique electronic characteristics and layered structure. Besides, g-C3N4
667
features high thermal and chemical stability and can be facilely attained from diverse sources. Thus,
668
g-C3N4 shows appealing prospect as novel carbon-based sorbents for Hg0 removal. However, the
669
performance of g-C3N4 is significantly affected by gas components. Some practical industrial gas
670
streams are extremely complex, and often simultaneously contain multiple gas components such as
671
H2O, NOx, HCl, H2S, SO2, CO, SO3, VOCs, etc. Thus much more work should be conducted to
672
further improve the stability of these carbon-based adsorbents in the presence of H2O, NOx, HCl,
673
H2S, SO2, CO, SO3, VOCs, etc., and reveal the effects of these gas components on Hg0 removal.
674
Furthermore, the disposal of spent sorbents after mercury capture also plays an important role in
675
mercury emission control by adsorption technique. Generally, the spent sorbents can be regenerated
676
and reused after heating treatment at middle temperature under nitrogen stream.
677
Acknowledgements
678
This work is supported by the National Natural Science Foundation of China (51576094;
679
U1710108), and the Senior Talent Foundation of Jiangsu University (18JDG017).
680
References
681
[1] Reddy BM, Durgasri N, Kumar TV, Bhargava SK (2012) Abatement of gas-phase mercury-recent
682
developments. Catal Rev 54: 344-398. 35
683
[2] Li H, Wu C, Li Y, Li L, Zhang J (2012) Role of flue gas components on mercury oxidation over TiO2
684
Supported MnOx-CeO2 mixed-oxide at low temperature. J Hazard Mater 243: 117-123.
685
[3] Liu YX, Zhang J, Yin Y (2014) Study on absorption of elemental mercury from flue gas by UV/H2O2: Process
686
parameters and reaction mechanism. Chem Eng J 249: 72-78.
687
[4] Jampaiah D, Ippolito SJ, Sabri YM, Reddy BM, Bhargava SK (2015) Highly efficient nanosized Mn and Fe
688
co-doped ceria-based solid solutions for elemental mercury removal at low flue gas temperatures. Catal Sci
689
Technol 5: 2913-2924.
690
[5] Jampaiah D, Ippolito SJ, Sabri YM, Tardio J, Selvakannan PR, Nafady A, Reddy BM, Bhargava SK (2016)
691
Ceria-zirconia modified MnOx catalysts for gaseous elemental mercury oxidation and adsorption. Catal. Sci.
692
Technol. 6: 1792-1803.
693
[6] Pacyna EG, Pacyna J, Sundseth K, Munthe J, Kindbom K, Wilson S, Steenhuisen
694
Global emission of mercury to the atmosphere from anthropogenic sources in 2005 and projections to 2020.
695
Atmos. Environ. 44: 2487-2499.
696
[7] Krabbenhoft DP, Sunderland EM (2013) Global change and mercury. Science 341: 1457-1458.
697
[8] Wang Y, Xu H, Liu YX (2019) Oxidative absorption of elemental mercury from flue gas using modified
698
Fenton-like wet scrubbing system. Energy Fuels 33: 3208-3033.
699
[9] Wang SX, Zhang L, Li GH, Wu Y, Hao JM, Pirrone N, Sprovieri F, Ancora MP (2010) Mercury emission and
700
speciation of coal-fired power plants in China. Atmos. Chem. Phys. 10: 1183-1192.
701
[10] Liu YX, Zhang J, Pan J (2014) Photochemical oxidation removal of Hg0 from flue gas containing SO2/NO by
702
ultraviolet irradiation/hydrogen peroxide (UV/H2O2) process. Energy Fuels 28: 2135-2143.
703
[11] Liu YX, Li Y, Xu H, Xu J (2019) Oxidation removal of gaseous Hg0 using enhanced-Fenton system in a
704
bubble column reactor. Fuel 246: 358-364.
705
[12] Liu YX, Wang Y, Wang Q, Pan J, Zhang Y, Zhang J (2015) A study on removal of elemental mercury in flue
706
gas using Fenton solution. J Hazard Mater 292: 164-172.
707
[13] Liu YX, Zhou J, Zhang Y, Pan J, Wang Q, Zhang J (2015) Removal of Hg0 and simultaneous removal of
36
F, Maxson P (2010)
708
Hg0/SO2/NO in flue gas using two Fenton-like reagents in a spray reactor. Fuel 145: 180-188.
709
[14] Liu YX, Wang Q (2014) Removal of elemental mercury from flue gas by thermally activated ammonium
710
persulfate in a bubble column reactor. Environ Sci Technol 48: 12181-12189.
711
[15] Liu YX, Wang, Y (2019) Gaseous elemental mercury removal using VUV and heat coactivation of
712
oxone/H2O/O2 in a VUV-spraying reactor. Fuel 243: 352-361.
713
[16] Liu YX, Wang Y (2018) Elemental mercury removal from flue gas using heat and Co2+/Fe2+ coactivated
714
oxone oxidation system. Chem Eng J 348: 464-475.
715
[17] Liu YX, Wang Y (2018) Removal of Hg0 from simulated flue gas by ultraviolet light/heat/persulfate process
716
in an UV-impinging stream reactor. Energy Fuels 32: 12416-12425.
717
[18] Li H, Wu S, Wu CY, Wang J, Li L, Shih K (2015) SCR atmosphere induced reduction of oxidized mercury
718
over CuO-CeO2/TiO2 catalyst. Environ Sci Technol 49: 7373-7379.
719
[19] Li J, Yan N, Qu Z, Qiao S, Yang S, Liu P, Jia J (2010) Catalytic oxidation of elemental mercury over the
720
modified catalyst Mn/α-Al2O3 at lower temperatures. Environ Sci Technol 44: 426-431.
721
[20] Zhao L, Li C, Wang Y, Wu H, Gao L, Zhang J, Zeng G (2016) Simultaneous removal of elemental mercury
722
and NO from simulated flue gas using a CeO2 modified V2O5-WO3/TiO2 catalyst. Catal Sci Technol 7:
723
1745-2010.
724
[21] Wu J, Li C, Zhao X, Wu Q, Qi X, Chen X, Hu T, Cao Y (2015) Photocatalytic oxidation of gas-phase Hg0 by
725
CuO/TiO2. Appl Catal B-Environ 176: 559-569.
726
[22] Sun X, Wu J, Liu Q, Tian F (2018) Mechanism insights into the enhanced activity and stability of
727
hierarchical bismuth oxyiodide microspheres with selectively exposed (001) or (110) facets for photocatalytic
728
oxidation of gaseous mercury. Appl Surf Sci 455: 864-875.
729
[23] Patiphatpanya P, Phuruangrat A, Thongtem S, Thongtem T (2017) Microwave-assisted synthesis and
730
characterization of BiOIO3 nanoplates for photocatalysis. Mater Lett 209: 264-267.
731
[24] Liu DJ, Zhou WG, Wu J (2017) Effect of Ce and La on the activity of CuO/ZSM-5 and MnOx/ZSM-5
37
732
composites for elemental mercury removal at low temperature. Fuel 194: 115-122.
733
[25] Yang W, Hussain A, Zhang J, Liu YX (2018) Removal of elemental mercury from flue gas using red mud
734
impregnated by KBr and KI reagent. Chem Eng J 341: 483–494.
735
[26] Liu DJ, Zhou WG, Wu J (2019) Kinetic behavior of elemental mercury sorption on cerium- and
736
lanthanum-based composite oxides. Surf Rev Lett 26: 1850141.
737
[27] Li G, Wu Q, Wang S, Li Z, Liang H, Tang Y, Zhao M, Chen L, Liu K, Wang F (2017) The influence of flue
738
gas components and activated carbon injection on mercury capture of municipal solid waste incineration in China.
739
Chem Eng J 326: 561-569.
740
[28] Sun P, Zhang B, Zeng X, Luo G, Li X, Yao H, Zheng C (2017) Deep study on effects of activated carbon’s
741
oxygen functional groups. Fuel 200: 100-106.
742
[29] De M, Azargohar R, Dalai AK, Shewchuk SR (2013) Mercury removal by bio-char based modified activated
743
carbons. Fuel 103: 570-578.
744
[30] Liu YX, Adewuyi YG (2016) A review on removal of elemental mercury from flue gas using advanced
745
oxidation process: Chemistry and process. Chem Eng Res Des 112: 199-250.
746
[31] Sowlat MH, Kakavandi B, Lotfi S, Yunesian M, Abdollahi M, Kalantary RR (2017) A systematic review on
747
the efficiency of cerium-impregnated activated carbons for the removal of gas-phase, elemental mercury from flue
748
gas. Environ Sci Pollut Res 24: 12092-12103.
749
[32] Xu W, Hussain A, Liu YX (2018) A Review on modification methods of adsorbents for elemental mercury
750
from flue gas. Chem Eng J 346: 692-711.
751
[33] Yang W, Adewuyi YG, Hussain A, Liu YX (2019) Recent developments on gas-solid heterogeneous
752
oxidation removal of elemental mercury from flue gas. Environ Chem Lett 17: 19-47.
753
[34] Chalkidis A, Jampaiah D, Hartley PG, Sabri YM, Bhargava SK (2020) Mercury in natural gas streams: A
754
review of materials and processes for abatement and remediation. J Hazard Mater 382: 121036.
755
[35] Liu H, Chang L, Liu W, Xiong Z, Zhao Y, Zhang J (2020) Advances in mercury removal from coal-fired flue
38
756
gas by mineral adsorbents. Chem Eng J 379: 122263.
757
[36] Fan L, Ling L, Wang B, Zhang R (2016) The adsorption of mercury species and catalytic oxidation of Hg0 on
758
the metal-loaded activated carbon. Appl Catal A-Gen 520: 13-23.
759
[37] Sano A, Takaoka M, Shiota K (2017) Vapor-phase elemental mercury adsorption by activated carbon
760
co-impregnated with sulfur and chlorine. Chem Eng J 315: 598-607.
761
[38] Wang Y, Li C, Zhao L, Xie Y, Zhang X, Zeng G, Wu H, Zhang J (2016) Study on the removal of elemental
762
mercury from simulated flue gas by Fe2O3-CeO2/AC at low temperature. Environ Sci Pollut Res 23: 5099-5110.
763
[39] Ie I, Hung C, Jen Y, Yuan C, Chen W (2013) Adsorption of vapor-phase elemental mercury (Hg0) and
764
mercury chloride (HgCl2) with innovative composite activated carbons impregnated with Na2S and S0 in different
765
sequences. Chem Eng J 229: 469-476.
766
[40] Rungnim C Promarak V, Hannongbua S, Kungwan N, Namuangruk, S (2016) Complete reaction
767
mechanisms of mercury oxidation on halogenated activated carbon. J Hazard Mater 310: 253-260.
768
[41] Wang X, Wang L, Bian Z, Ning P, Wang P, Wang F, Ma Y (2018) Adsorption of gaseous elemental mercury
769
by ferric chloride-modified activated carbon under low temperature conditions. Clean-Soil Air Water 46:1800351.
770
[42] Chen Y, Guo X, Wu F, Huang Y, Yin Z (2018) Experimental and theoretical studies for the mechanism of
771
mercury oxidation over chlorine and cupric impregnated activated carbon. Appl Surf Sci 458: 790-799.
772
[43] Tong L, Yue T, Zuo P, Zhang X, Wang C, Gao J, Wang K (2017) Effect of characteristics of KI-impregnated
773
activated carbon and flue gas components on Hg0 removal. Fuel 197: 1-7.
774
[44] Zhong L, Li W, Zhang Y, Norris P, Cao Y, Pan W (2017) Kinetic studies of mercury adsorption in activated
775
carbon modified by iodine steam vapor deposition method. Fuel 188: 343-351.
776
[45] Hong D, Zhou J, Hu C, Zhou Q, Mao J, Qin Q (2019) Mercury removal mechanism of AC prepared by
777
one-step activation with ZnCl2. Fuel 235: 326-335.
39
778
[46] Yue C, Wang J, Han L, Chang L, Hu Y, Wang H (2015) Effects of pretreatment of Pd/AC sorbents on the
779
removal of Hg0 from coal derived fuel gas. Fuel Process Technol 135: 125-132.
780
[47] Han L, He X, Yue C, Hu Y, Li L, Chang L, Wang H, Wang J (2016) Fe doping Pd/AC sorbent efficiently
781
improving the Hg0 removal from the coal-derived fuel gas. Fuel 182: 64-72.
782
[48] Gómez-Giménez C, Izquierdo MT, Obras-Loscertales M, Diego LF, García-Labiano F, Adánez J (2017)
783
Mercury capture by a structured Au/C regenerable sorbent under oxycoal combustion representative and real
784
conditions. Fuel 207: 821-829.
785
[49] Wu J, Zhao Z, Huang T, Zhang J, Tian H, Zhao X, Zhao L, He P, Gao K (2017) Removal of elemental
786
mercury by Ce-Mn co-modified activated carbon catalyst. Catal Commun 93: 62-66.
787
[50] Zhu Y, Han X, Huang Z, Hou Y, Guo Y, Wu M (2018) Superior activity of CeO2 modified V2O5/AC catalyst
788
for mercury removal at low temperature. Chem Eng J 337: 741-749.
789
[51] Xie J, Xu H, Qu Z, Huang W, Chen W, Ma Y, Zhao S, Liu P, Yan N (2014) Sn-Mn binary metal oxides as
790
non-carbon sorbent for mercury removal in a wide-temperature window. J Colloid Interf Sci 428: 121-127.
791
[52] Yang S, Wang D, Liu H, Liu G, Xie X, Xu Z, Liu Z (2019) Highly stable activated carbon composite
792
material to selectively capture gas phase elemental mercury from smelting flue gas: Copper polysulfide
793
modification. Chem Eng J 358: 1235-1242.
794
[53] Huo Q, Wang Y, Chen H, Han L, Wang J, Bao W, Chang L, Xie K (2019) ZnS/AC sorbent derived from the
795
high sulfur petroleum coke for mercury removal. Fuel Process Technol 191: 36-43.
796
[54] Shi M, Luo G, Xu Y, Zou R, Zhu H, Hu J, Li X, Yao H (2019) Using H2S plasma to modify activated carbon
797
for elemental mercury removal. Fuel 254: 115549.
798
[55] Ma J, Li C, Zhao L, Zhang J, Zeng G, Zhang X, Xie Y (2015) Study on removal of elemental mercury from
799
simulated flue gas over activated coke treated by acid. Appl Surf Sci 329: 292-300.
40
800
[56] Tao S, Li C, Fan X, Zeng G, Lu P, Zhang X, Wen Q, Zhao W, Luo D, Fan C (2012) Activated coke
801
impregnated with cerium chloride used for elemental mercury removal from simulated flue gas. Chem Eng J 201:
802
547-556.
803
[57] Xie Y, Li C, Zhao L, Zhang J, Zeng G, Zhang X, Zhang W, Tao S (2015) Experimental study on Hg0
804
removal from flue gas over columnar MnOx-CeO2 activated coke. Appl Surf Sci 333: 59-67.
805
[58] Wu H, Li C, Zhao L, Zhang J, Zeng G, Xie Y, Zhang X, Wang Y (2015) Removal of gaseous elemental
806
mercury by cylindrical activated coke loaded with CoOx-CeO2 from simulated coal combustion flue gas. Energy
807
Fuels 29: 6747-6757.
808
[59] Zhao B, Yi H, Tang X, Li Q, Liu D, Gao F (2016) Copper modified activated coke for mercury removal from
809
coal-fired flue gas. Chem Eng J 286: 585-593.
810
[60] Chen J, Li C, Li S, Lu P, Gao L, Du X, Yi Y (2018) Simultaneous removal of HCHO and elemental mercury
811
from flue gas over Co-Ce oxides supported on activated coke impregnated by sulfuric acid. Chem Eng J 338:
812
358-368.
813
[61] Liu M, Li C, Zeng Q, Du X, Gao L, Li S, Zhai Y (2019) Study on removal of elemental mercury over
814
MoO3-CeO2/cylindrical activated coke in the presence of SO2 by Hg-temperature-programmed desorption. Chem
815
Eng J 371: 666-678.
816
[62] Zeng Q, Li C, Li S, Liu M, Du X, Gao L, Zhai Y (2019) Adsorption and oxidation of elemental mercury from
817
coal-fired flue gas over activated coke loaded with Mn-Ni oxides. Environ Sci Pollut Res 26: 15420-15435.
818
[63] Zhang H, Chen J, Zhao K, Niu Q, Wang L (2016) Removal of vapor-phase elemental mercury from
819
simulated syngas using semi-coke modified by Mn/Ce doping. J Fuel Chem Technol 44: 394-400.
820
[64] Zhang X, Dong Y, Cui L, An D, Feng Y (2018) Removal of elemental mercury from coal pyrolysis gas using
821
Fe-Ce oxides supported on lignite semi-coke modified by the hydrothermal impregnation method. Energy Fuels
41
822
32: 12861-12870.
823
[65] Zhang H, Zhao K, Gao Y, Tian Y, Liang P (2017) Inhibitory effects of water vapor on elemental mercury
824
removal performance over cerium-oxide-modified semi-coke. Chem Eng J 324: 279-286.
825
[66] Zhang H, Sun H, Zhao K, Han Y, Wu J, Jiao T, Liang P (2018) Influences of water vapor and fly ash on
826
elemental mercury removal over cerium-oxide-modified semi-coke. Fuel 217: 211-217.
827
[67] Xiao Y, Pudasainee D, Gupta R, Xu Z, Diao Y (2017) Elemental mercury reaction chemistry on brominated
828
petroleum cokes. Carbon 124: 89-96.
829
[68] Xiao Y, Pudasainee D, Gupta R, Xu Z, Diao Y (2017) Bromination of petroleum coke for elemental mercury
830
capture. J Hazard Mater 336: 232-239.
831
[69] Xu Y, Zeng X, Luo G, Zhang B, Xu P, Xu M, Yao H (2016) Chlorine-Char composite synthesized by
832
co-pyrolysis of biomass wastes and polyvinyl chloride for elemental mercury removal. Fuel 183: 73-79.
833
[70] Xu H, Shen B, Yuan P, Lu F, Tian L, Zhang X (2016) The adsorption mechanism of elemental mercury by
834
HNO3-modified bamboo char. Fuel Process Technol 154: 139-146.
835
[71] Shu T, Lu P, He N (2013) Mercury adsorption of modified mulberry twig chars in a simulated flue gas.
836
Bioresource Technol 136: 182-187.
837
[72] Zeng J, Li C, Zhao L, Gao L, Du X, Zhang J, Tang L, Zeng G (2017) Removal of elemental mercury from
838
simulated flue gas over peanut shells carbon loaded with iodine ions, manganese oxides, and zirconium dioxide.
839
Energy Fuels 31: 13909-13920.
840
[73] Hu Y, Wang S, Wang Q, He Z, Lin X, Xu S, Ji H, Li Y (2017) Effect of different pretreatments on the
841
thermal degradation of seaweed biomass. P Combust Inst 36: 2271-2281.
842
[74] Mosier N, Wyman C, Dale B, Elander R, Lee YY, Ladisch M (2005) Features of promising technologies for
843
pretreatment of lignocellulosic biomass. Bioresource Technol 96: 673-686.
844
[75] Zhu C, Duan Y, Wu C, Zhou Q, She M, Yao T, Zhang J (2016) Mercury removal and synergistic capture of
845
SO2/NO by ammonium halides modified rice husk char. Fuel 172: 160-169. 42
846
[76] Xu W, Adewuyi YG, Liu YX (2018) Removal of elemental mercury from flue gas using CuOx and CeO2
847
modified rice straw chars enhanced by ultrasound. Fuel Process Technol 170: 21-31.
848
[77] Yang R, Diao Y, Abayneh B (2018) Removal of Hg0 from simulated flue gas over silver-loaded rice husk
849
gasification char. R Soc Open Sci 5: 180248.
850
[78] Yang W, Chen H, Han X, Ding S, Shan Y, Liu YX (2020) Preparation of magnetic Co-Fe modified porous
851
carbon from agricultural wastes by microwave and steam activation for mercury removal. J Hazard Mater 381:
852
120981.
853
[79] Zhou J, Liu YX, Pan J (2017) Removal of elemental mercury from flue gas using wheat straw chars modified
854
by K2FeO4 reagent. Environ Technol 38: 3047-3054.
855
[80] Yang W, Liu YX, Wang Q, Pan J (2017) Removal of elemental mercury from flue gas using wheat straw
856
chars modified by Mn-Ce mixed oxides with ultrasonic-assisted impregnation. Chem Eng J 326: 169-181.
857
[81] Yang W, Li Y, Shi S, Chen H, Shan Y, Liu YX (2019) Mercury removal from flue gas by magnetic
858
iron-copper oxide modified porous char derived from biomass materials. Fuel 256: 115977.
859
[82] Niu Q, Luo J, Xia Y, Sun S, Chen Q (2017) Surface modification of bio-char by dielectric barrier discharge
860
plasma for Hg0 removal. Fuel Process Technol 156: 310-316.
861
[83] Gao L, Li C, Zhang J, Du X, Li S, Zeng J, Yi Y, Zeng G (2018) Simultaneous removal of NO and Hg0 from
862
simulated flue gas over CoOx-CeO2 loaded biomass activated carbon derived from maize straw at low
863
temperatures. Chem Eng J 342: 339-349.
864
[84] Shan Y, Yang W, Li Y, Chen H, Liu YX (2019) Removal of elemental mercury from flue gas using
865
microwave/ultrasound-activated Ce-Fe magnetic porous carbon derived from biomass straw. Energy Fuels 33:
866
8394-8402.
867
[85] Li G, Wang S, Wang F, Shen B (2017) Mechanism identification of temperature influence on mercury
868
adsorption capacity of different halides modified bio-chars. Chem Eng J 315: 251-261.
869
[86] Shan Y, Yang W, Li Y, Liu YX, Pan J (2019) Preparation of microwave-activated magnetic bio-char
870
adsorbent and study on removal of elemental mercury from flue gas. Sci Total Environ 697: 134049.
871
[87] Luo J, Jin M, Ye L, Cao Y, Yan Y, Du R, Yoshiie, R, Ueki Y, Naruse I, Lin C, Lee Y (2019) Removal of
872
gaseous elemental mercury by hydrogen chloride non-thermal plasma modified biochar. J Hazard Mater 377:
873
132-141.
43
874
[88] Wang T, Liu J, Zhang Y, Zhang H, Chen W, Norris P, Pan W (2018) Use of a non-thermal plasma technique
875
to increase the number of chlorine active sites on biochar for improved mercury removal. Chem Eng J 331:
876
536-544.
877
[89] Zhang H, Wang T, Sui Z, Zhang Y, Sun B, Pan W (2019) Enhanced mercury removal by transplanting
878
sulfur-containing functional groups to biochar through plasma. Fuel 253: 703-712.
879
[90] Gao L, Li C, Li S, Zhang W, Du X, Huang L, Zhu Y, Zhai Y, Zeng G (2019) Superior performance and
880
resistance to SO2 and H2O over CoOx-modifed MnOx/biomass activated carbons for simultaneous Hg0 and NO
881
removal. Chem Eng J 371: 781-795.
882
[91] Xu Y, Luo G, He S, Deng F, Pang Q, Xu Y, Yao H (2019) Efficient removal of elemental mercury by
883
magnetic chlorinated biochars derived from co-pyrolysis of Fe(NO3)3-laden wood and polyvinyl chloride waste.
884
Fuel 239: 982-990.
885
[92] Maddi B, Viamajala S, Varanasi S (2011) Comparative study of pyrolysis of algal biomass from natural lake
886
blooms with lignocellulosic biomass. Bioresource Technol 102: 11018-11026.
887
[93] Ding S, Liu YX (2020) Adsorption of CO2 from flue gas by novel seaweed-based KOH-activated porous
888
biochars. Fuel 260: 116382.
889
[94] Wang S, Xia Z, Hu Y, He Z, Uzoejinwa BB, Wang Q, Cao B, Xu S (2016) Co-pyrolysis mechanism of
890
seaweed polysaccharides and cellulose based on macroscopic experiments and molecular simulations. Bioresource
891
Technol 228: 305-314.
892
[95] Yang W, Xu W, Liu Z, Liu YX (2018) Removal of elemental mercury from flue gas using sargassum chars
893
modified by NH4Br reagent. Fuel 214: 196-206.
894
[96] Yang W, Shan Y, Ding S, Han X, Liu YX, Pan J (2019) Gas-phase elemental mercury removal using
895
ammonium chloride impregnated sargassum chars. Environ Technol 40: 1923-1936.
896
[97] Xu W, Pan J, Fan B, Liu YX (2019) Removal of gaseous elemental mercury using seaweed chars
897
impregnated by NH4Cl and NH4Br. J Clean Prod 216: 277-287.
898
[98] Liu Z, Yang W, Xu W, Liu YX (2018) Removal of elemental mercury by bio-chars derived from seaweed
899
impregnated with potassium iodine. Chem Eng J 339: 468-478.
900
[99] Liu Z, Adewuyi YG, Shi S, Chen H, Li Y, Liu DJ, Liu YX (2019) Removal of gaseous Hg0 using novel
44
901
seaweed biomass-based activated carbon. Chem Eng J 366: 41-49.
902
[100] Wang QH, Bellisario DO, Drahushuk LW, Jain RM, Kruss S, Landry MP, Mahajan SG, Shimizu SFE,
903
Ulissi ZW, Strano MS (2014) Low dimensional carbon materials for applications in mass and energy transport.
904
Chem Mater 26: 172-183.
905
[101] Liu DJ, Zhou W, Wu J, Huang T (2018) Fractal characterization of graphene oxide nanosheet. Mater Lett
906
220: 40-43.
907
[102] Novoselov KS, Geim AK, Morozov SV, Jiang D, Zhang Y, Dubonos SV, Grigorieva IV, Firsov AA (2004)
908
Electric field effect in atomically thin carbon films. Science 306: 666-669.
909
[103] Zhou C, Zhu H, Wang Q, Wang J, Cheng J, Guo Y, Zhou, X, Bai R (2017) Adsorption of mercury(ii) with
910
an Fe3O4 magnetic polypyrrole-graphene oxide nanocomposite. RSC Adv 7: 18466-18479.
911
[104] Zhao Y, Nie G, Ma X, Xu P, Zhao X (2019) Peroxymonosulfate catalyzed by rGO assisted CoFe2O4
912
catalyst for removing Hg0 from flue gas in heterogeneous system. Environ Pollut 249: 868-877.
913
[105] Xu, H, Qu Z, Zong C, Huang W, Quan, F, Yan N (2015) MnOx/graphene for the catalytic oxidation and
914
adsorption of elemental mercury. Environ Sci Technol 49: 6823-6830.
915
[106] Xu H, Qu Z, Huang W, Mei J, Chen W, Zhao S, Yan N (2015) Regenerable Ag/graphene sorbent for
916
elemental mercury capture at ambient temperature. Colloid Surface A 476: 83-89.
917
[107] Ma Y, Mu B, Zhang X, Yuan D, Ma C, Xu H, Qu Z, Fang S (2019) Graphene enhanced Mn-Ce binary
918
metal oxides for catalytic oxidation and adsorption of elemental mercury from coal-fired flue gas. Chem Eng J
919
358: 1499-1506.
920
[108] Liu Y, Tian C, Yan B, Lu Q, Xie Y, Chen J, Gupta R, Xu Z, Kuznicki SM, Liu Q, Zeng H (2015)
921
Nanocomposites of graphene oxide, Ag nanoparticles, and magnetic ferrite nanoparticles for elemental mercury
922
(Hg0) removal. RSC Adv 5: 15634-15640.
45
923
[109] An D, Zhang X, Dong Y (2018) Performance of Mn-Fe-Ce/GO-x for catalytic oxidation of Hg0 and
924
selective catalytic reduction of NOx in the same temperature range. Catalysts 8: 399.
925
[110] Ma Y, Mu B, Zhang X, Qu Z, Gao L, Li B, Tian J (2019) Ag-Fe3O4@rGO ternary magnetic adsorbent for
926
gaseous elemental mercury removal from coal-fired flue gas. Fuel 239: 579-586.
927
[111] Meeprasert J, Junkaew A, Rungnim C, Kunaseth M, Kungwan N, Promarak V, Namuangruk S (2016)
928
Capability of defective graphene-supported Pd13 and Ag13 particles for mercury adsorption. Appl Surf Sci 364:
929
166-175.
930
[112] Jungsuttiwong S, Wongnongwa Y, Namuangruk S, Kungwan N, Promarak V, Kunaseth M (2016) Density
931
functional theory study of elemental mercury adsorption on boron doped graphene surface decorated by transition
932
metals. Appl Surf Sci 362: 140-145.
933
[113] Zhao C, Wu H (2017). Density functional investigation of mercury and arsenic adsorption on nitrogen
934
doped graphene decorated with palladium clusters: a promising heavy metal sensing material in farmland. Appl
935
Surf Sci 399: 55-66.
936
[114] Liu Z, Zhang Y, Wang B, Chen H, Cheng X, Huang Z (2018) DFT study on Al-doped defective graphene
937
towards adsorption of elemental mercury. Appl Surf Sci 427: 547-553.
938
[115] Tasis D, Tagmatarchis N, Bianco A, Prato M (2006) Chemistry of carbon nanotubes. Chem Rev 106:
939
1105-1113.
940
[116] Huang B, Yue J, Wei Y, Huang X, Tang X, Du Z (2019) Enhanced microwave absorption properties of
941
carbon nanofibers functionalized by FeCo coatings. Appl Surf Sci 483: 98-105.
942
[117] Zhao B, Liu X, Zhou Z, Shao H, Xu M (2016) Catalytic oxidation of elemental mercury by Mn-Mo/CNT at
943
low temperature. Chem Eng J 284: 1233-1241.
944
[118] Ma Y, Zhang D, Wu J, Liang P, Zhang H (2018) Fe-Ce mixed oxides supported on carbon nanotubes for
46
945
simultaneous removal of NO and Hg0 in flue gas. Ind Eng Chem Res 57: 3187-3194.
946
[119] Yao Y, Velpari V, Economy J (2014) Design of sulfur treated activated carbon fibers for gas phase
947
elemental mercury removal. Fuel 116: 560-565.
948
[120] Yang J, Zhao Y, Liang S, Zhang S, Ma S, Li H, Zhang J, Zheng C (2018) Magnetic iron-manganese binary
949
oxide supported on carbon nanofiber (Fe3-xMnxO4/CNF) for efficient removal of Hg0 from coal combustion flue
950
gas. Chem Eng J 334: 216-224.
951
[121] Xia Y, Liao Z, Zheng Y, Zhou Z (2018) Highly dispersed Mn-Ce binary metal oxides supported on carbon
952
nanofibers for Hg0 removal from coal-fired flue gas. Appl Sci 8: 2501.
953
[122] Romero-Anaya AJ, Lillo-Ródenas MA, Linares-Solano A (2014) Activation of a spherical carbon for
954
toluene adsorption at low concentration. Carbon 77: 616-626.
955
[123] Ludwinowicz J, Jaroniec M (2015) Potassium salt-assisted synthesis of highly microporous carbon spheres
956
for CO2 adsorption. Carbon 82: 297-303.
957
[124] Xu H, Jia J, Guo Y, Qu Z, Liao Y, Xie J, Shangguan W, Yan N (2018) Design of 3D MnO2-Carbon sphere
958
composite for the catalytic oxidation and adsorption of elemental mercury. J Hazard Mater 342: 69-76.
959
[125] Zhang C, Song W, Zhang X, Li R, Zhao S, Fan C (2018) Synthesis characterization and evaluation of
960
resin-based carbon spheres modified by oxygen functional groups for gaseous elemental mercury capture. J Mater
961
Sci 53: 9429-9448.
962
[126] Zhang C, Song W, Zhang X, Li R, Zhao S, Fan C (2019) Synthesis and evaluation of activated carbon
963
spheres with copper modification for gaseous elemental mercury removal. J Porous Mater 26: 693-703.
964
[127] Zhang C, Song W, Zhang X, Li R, Zhao S, Fan C (2019)
965
spheres by grafting and coordinating reactions for elemental mercury removal. J Mater Sci 54: 2836-2852.
966
[128] Chen T, Guo S, Yang J, Xu Y, Sun J, Wei D, Chen Z, Zhao B, Ding W (2017) In situ activated
47
Synthesis of CeO2-modified activated carbon
967
nitrogen-doped carbon by embeded nickel via Mott-Schottky effect for oxygen reduction reaction.
968
ChemPhysChem 18: 3454-3461.
969
[129] Rowsell JLC, Yaghi OM (2004) Metal-organic frameworks: a new class of porous materials. Micropor
970
Mesopor Mat 73: 3-14.
971
[130] Jiang H, Wang C, Wang H, Zhang M (2016) Synthesis of highly efficient MnOx catalyst for
972
low-temperature NH3-SCR prepared from Mn-MOF-74 template. Mater Lett 168: 17-19.
973
[131] Li Y, Wang L, Fan H, Shangguan J, Wang H, Mi J (2015) Removal of sulfur compounds by a copper-based
974
metal organic framework under ambient conditions. Energy Fuels 29: 298-304.
975
[132] Sun X, Shi Y, Zhang W, Li C, Zhao Q, Gao J, Li X (2018) A new type Ni-MOF catalyst with high stability
976
for selective catalytic reduction of NOx with NH3. Catal Commun 114: 104-108.
977
[133] Yaghi OM, Li H (1995) Hydrothermal synthesis of a metal-organic framework containing large rectangular
978
channel. J Am Chem Soc 117: 10401-10402.
979
[134] Li H, Eddaoudi M, O’Keeffe M, Yaghi OM (1999) Design and synthesis of an exceptionally stable and
980
highly porous metal-organic framework. Nature 402: 276-279.
981
[135] Kaye SS, Dailly A, Yaghi OM, Long JR (2007) Impact of preparation and handling on the hydrogen storage
982
properties of Zn4O(1, 4-benzenedicarboxylate)3(MOF-5). J Am Chem Soc 129: 14176-14177.
983
[136] Rosi NL, Eckert J, Eddaoudi M, Vodak DT, Kim J, O’Keeffe M, Yaghi OM (2003) Hydrogen storage in
984
microporous metal-organic frameworks. Science 300: 1127-1129.
985
[137] Bao Z, Alnemrat S, Yu L, Vasiliev I, Ren Q, Lu X, Deng S (2011) Adsorption of ethane, ethylene, propane,
986
and propylene on a magnesium-based metal-organic framework. Langmuir 27: 13554-13562.
987
[138] Wu X, Bao Z, Yuan B, Wang J, Sun Y, Luo H, Deng S (2013) Microwave synthesis and characterization of
988
MOF-74 (M=Ni, Mg) for gas separation. Micropor Mesopor Mat 180: 114-122.
48
989
[139] Lee JY, Farha OK, Roberts J, Scheidt KA, Nguyen SBT, Hupp JT (2009) Metal-organic framework
990
materials as catalysts. Chem Soc Rev 38: 1450-1459.
991
[140] Tan HY, Zhou Y, Yan YF, Wu DY, Hu WB, Shi XY (2017) Metal organic framework
992
Cu/MIL-53(Ce)-mediated synthesis of highly active and stable CO oxidation catalysts. Inorg Chem Commun 79:
993
74-77.
994
[141] Sun H, Zhang H, Mao H, Yu B, Han J, Bhat G (2019) Facile synthesis of the magnetic metal–organic
995
framework Fe3O4/Cu3(BTC)2 for efficient dye removal. Environ Chem Lett 17: 1091-1096.
996
[142] Kumar A, Rana A, Sharma G, Sharma S, Naushad M, Mola GT, Dhiman P, Stadler FJ (2018) Aerogels and
997
metal–organic frameworks for environmental remediation and energy production. Environ Chem Lett 16:
998
797-820.
999
[143] Liu Y, Li H, Liu J (2016) Theoretical prediction the removal of mercury from flue gas by MOFs. Fuel 184:
1000
474-480.
1001
[144] Zhang X, Shen B, Zhu S, Xu H, Tian L (2016) UiO-66 and its Br-modified derivates for elemental mercury
1002
removal. J Hazard Mater 320: 556-563.
1003
[145] Zhang X, Shen B, Shen F, Zhang X, Si M, Yuan P (2017) The behavior of the manganese-cerium loaded
1004
metal-organic framework in elemental mercury and NO removal from flue gas. Chem Eng J 326: 551-560.
1005
[146] Zhao S, Chen D, Xu H, Mei J, Qu Z, Liu P, Cui Y, Yan N (2018) Combined effects of Ag and UiO-66 for
1006
removal of elemental mercury from flue gas. Chemosphere 197: 65-72.
1007
[147] Chen D, Zhao S, Qu Z, Yan N (2018) Cu-BTC as a novel material for elemental mercury removal from
1008
sintering gas. Fuel 217: 297-305.
1009
[148] Zhao S, Mei J, Xu H, Liu W, Qu Z, Cui Y, Yan N (2018) Research of mercury removal from sintering flue
1010
gas of iron and steel by the open metal site of Mil-101(Cr). J Hazard Mater 351: 301-307.
49
1011
[149] Zhou J, Cao L, Wang Q, Tariq M, Xue Y, Zhou Z, Sun W, Yang J (2019) Enhanced Hg0 removal via
1012
α-MnO2 anchored to MIL-96(Al). Appl Surf Sci 483: 252-259.
1013
[150] Yang J, Zhu W, Qu W, Yang Z, Wang J, Zhang M, Li H (2019) Selenium functionalized metal-organic
1014
framework MIL-101 for efficient and permanent sequestration of mercury. Environ Sci Technol 53: 2260-2268.
1015
[151] Wang X, Blechert S, Antonietti M (2012) Polymeric graphitic carbon nitride for heterogeneous
1016
photocatalysis. ACS Catal 2: 1596-1606.
1017
[152] Kumar A, Thakur PR, Sharma G, Naushad M, Rana A, Mola GT, Stadler FJ (2019) Carbon nitride, metal
1018
nitrides, phosphides, chalcogenides, perovskites and carbides nanophotocatalysts for environmental applications.
1019
Environ Chem Lett 17: 655-682.
1020
[153] Liang Q, Li Z, Bai Y, Huang Z, Kang F, Yang Q (2017) Reduced-sized monolayer carbon nitride
1021
nanosheets for highly improved photoresponse for cell imaging and photocatalysis. Sci China Mater 60: 109-118.
1022
[154] Wang Y, Wang X, Antonietti M (2012) Polymeric graphitic carbon nitride as a heterogeneous
1023
organocatalyst: from photochemistry to multipurpose catalysis to sustainable chemistry. Angew Chem Int Ed 51:
1024
68-89.
1025
[155] Wang X, Maeda K, Thomas A, Takanabe K, Xin G, Carlsson JM, Domen K, Antonietti MA (2009)
1026
Metal-free polymeric photocatalyst for hydrogen production from water under visible light. Nat Mater 8: 76-82.
1027
[156] Xiao J, Xie Y, Cao H, Wang Y, Guo Z, Chen Y (2016) Towards effective design of active nanocarbon
1028
materials for integrating visible-light photocatalysis with ozonation. Carbon 107: 658-666.
1029
[157] Dong G, Yang L, Wang F, Zang L, Wang C (2016) Removal of nitric oxide through visible light
1030
photocatalysis by g-C3N4 modified with perylene imides. ACS Catal 6: 6511-6519.
1031
[158] Tang J, Guo R, Pan W, Zhou W, Huang C (2019) Visible light activated photocatalytic behaviour of Eu (III)
1032
modified g-C3N4 for CO2 reduction and H2 evolution. Appl Surf Sci 467-468: 206-212.
50
1033
[159] Lu C, Wu J, Liu DJ (2018) Graphitic carbon nitride for elemental mercury capture. Mater Lett 227:
1034
308-310.
1035
[160] Liu DJ, Lu C, Wu J (2018) CuO/g-C3N4 nanocomposite for elemental mercury capture at low temperature. J
1036
Nanopart Res 20: 277.
1037
[161] Liu DJ, Lu C, Wu J (2018) Gaseous mercury capture by copper-activated nanoporous carbon nitride.
1038
Energy Fuels 32: 8287-8295.
1039
[162] Niu P, Zhang L, Liu G, Cheng H (2012) Graphene-like carbon nitride nanosheets for improved
1040
photocatalytic activities. Adv Funct Mater 22: 4763-4770.
1041
[163] Xu J, Zhang L, Shi R, Zhu Y (2013) Chemical exfoliation of graphitic carbon nitride for efficient
1042
heterogeneous photocatalysis. J Mater Chem A 1: 14766-14772.
1043
[164] Liu DJ, Zhang Z, Wu J (2019) Elemental mercury removal by MnO2 nanoparticle decorated carbon nitride
1044
nanosheet. Energy Fuels 33: 3089-3097.
1045
[165] Zhang Z, Wu J, Liu DJ (2019) Co3O4/g-C3N4 hybrids for gas-phase Hg0 removal at low temperature.
1046
Processes 7: 279.
1047
[166] Liu DJ, Lu C, Wu J (2018) Elemental mercury adsorption by cupric chloride-modified mesoporous carbon
1048
aerogel. Colloids Interfaces 2: 66.
1049
[167] Zhang H, Zhang D, Wang J, Xu W, Yang D, Jiao T, Zhang W, Liang P (2019) Simultaneous removal of
1050
Hg0 and H2S at a high space velocity by water resistant SnO2/carbon aerogel. J Hazard Mater 371: 123-129.
1051
[168] Ma Y, Qi P, Ju J, Wang Q, Hao L, Wang R, Sui K, Tan Y (2019) Gelatin/alginate composite nanofiber
1052
membranes for effective and even adsorption of cationic dyes. Compos Part B-Eng 162: 671-677.
1053
[169] Liu DJ, Wang Q, Wu J, Liu YX (2019) A review of sorbents for high-temperature hydrogen sulfide removal
1054
from hot coal gas. Environ Chem Lett 17: 259-276.
51
1055
[170] Wu Z, Liang H, Hu B, Yu S (2018) Emerging carbon-nanofiber aerogels: chemosynthesis versus
1056
biosynthesis. Angew Chem Int Ed 57: 15646-15662.
1057
[171] Wang Y, Han X, Liu YX. (2019) Removal of Carbon Monoxide from Simulated Flue Gas Using Two New
1058
Fenton Systems: Mechanism and Kinetics. Environ Sci Technol 51:11950–11959.
1059
[172] Shen FH, Liu J, Dong YC. (2019) Elemental mercury removal from syngas by porous carbon-supported
1060
CuCl2 sorbents. Fuel 239: 138-144.
1061
[173] Wang Y, Liu YX, Liu Y. (2019) Elimination of nitric oxide using new Fenton process based on synergistic
1062
catalysis: Optimization and mechanism. Chem Eng J 372: 92-98.
1063
[174] Shen FH, Liu J. (2019) Design of O2/SO2 dual-doped porous carbon as superior sorbent for elemental
1064
mercury removal from flue gas. J Hazard Mater 366: 321-328.
1065
[175] Liu YX, Wang Y, Liu ZY, Wang Q. (2017) Oxidation Removal of Nitric Oxide from Flue Gas Using UV
1066
Photolysis of Aqueous Hypochlorite. Environ Sci Technol 51:11950-11959.
1067
[176] Wang Y, Wang ZL, Pan JF, Liu YX. (2019) Removal of Hydrogen Sulfide Using Fenton Reagent in A
1068
Spraying Reactor. Fuel 239: 70-75.
1069
[177] Shen FH, Liu J. (2019) Development of O2 and NO co-doped porous carbon as high-capacity mercury
1070
sorbent. Environ Sci Technol 53: 1725-1731.
1071
[178] Wang Y, Liu YX, Xu JJ. (2019) Separation of Hydrogen Sulfide from Gas Phase Using Ce3+/Mn2+-
1072
Enhanced Fenton-Like Oxidation System. Chem Eng J 359:1486-1492.
1073
[179] Liu DJ, Li B, Wu J. (2019)Sorbents for hydrogen sulfide capture from biogas at low temperature: a review.
1074
Environ Chem Lett . https://doi.org/10.1007/s10311-019-00925-6
1075
[180] Lu CY, Wei MY. (2007) Simultaneous removal of VOC and NO by activated carbon impregnated with
1076
transition metal catalysts in combustion flue gas. Fuel Process Technol 359:1486-1492
52
1077
Graphical Abstract
1078 1079 1080 1081 1082
1083 1084 1085
1. The prospect and limitation of low-dimensional carbon for Hg0 removal are commented.
1086
2. Bio-char, carbon nitride, and metal-organic framework are promising mercury sorbents.
1087
3. The performances and mechanisms of diverse carbon-based sorbents are fully discussed.
1088 1089
Declaration of Interest Statement
1090 1091 1092
53
1093
(1) All authors declare that we have no financial and personal relationships with other people,
1094
organizations or company that can inappropriately influence our work. The authors also state
1095
that the processing of this manuscript will not receive any organizational or personal
1096
interference.
1097
(2) All authors declare that the copyright of this manuscript is entirely determined by the
1098
submitting publisher and/or the journal. The authors have no interest disputes about this
1099
publishing rights or future commercial interests.
1100 1101
(3) All authors agree to the corresponding author's submission decision and ensure that there are no disputes of interest.
1102 1103
54
S1385-8947(19)32929-8 https://doi.org/10.1016/j.cej.2019.123514 CEJ 123514
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Chemical Engineering Journal
Received Date: Revised Date: Accepted Date:
14 September 2019 12 November 2019 15 November 2019
Please cite this article as: D. Liu, C. Li, J. Wu, Y. Liu, Novel Carbon-based Sorbents for Elemental Mercury Removal from Gas Streams: A Review, Chemical Engineering Journal (2019), doi: https://doi.org/10.1016/j.cej.2019.123514
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© 2019 Published by Elsevier B.V.
1
Novel Carbon-based Sorbents for Elemental Mercury Removal from
2
Gas Streams: A Review
3
Dongjing Liu 1, Chaoen Li 2, Jiang Wu 3, Yangxian Liu 1*
4 5 6 7
1 School
of Energy and Power Engineering, Jiangsu University, Zhenjiang 212013, China
2 College 3 College
of Mechanical Engineering, Tongji University, Shanghai 200092, China
of Energy and Mechanical Engineering, Shanghai University of Electric Power, Shanghai 200090, China
8 9 10
*Contact information: Tel.: +86-0511-88780211; Fax: +86-0511-88780211;
11
E-mail: [email protected] (X.Y. Liu)
12 13
Abstract: Mercury emission, derived from natural gas exploitation, metal sintering, coal
14
gasification and combustion, gold mining, etc., has posed great threaten to the environment and
15
human beings due to its volatility, mobility, toxicity, and bioaccumulation in ecosystem and food
16
chains. Adsorption using carbon materials is regarded as one of the most promising techniques for
17
mercury emission control due to its simple equipment, convenient operation, high removing
18
efficacy, less secondary pollution, etc. This review comments the new research progress of
19
elemental mercury capture by novel carbon-based sorbents in recent five years, particularly
20
emerging carbon materials, such as bio-chars, graphene and graphene oxide, carbon nanotubes and
21
nanofibers, carbon spheres, carbon aerogels, metal-organic frameworks, and graphitic carbon
22
nitrides. The mercury removal performances and reaction mechanisms of diverse carbon-based
1
23
sorbents along with their merits and drawbacks are fully discussed, which aims to strengthen the
24
understanding of this emerging research topic and outline future research directions for the
25
development of sustainable, recyclable, and cost-effective carbon-based mercury sorbents.
26
Keywords: Elemental mercury; graphitic carbon nitride; metal-organic framework; graphene;
27
carbon sphere; bio-char
28
1. Introduction
29
Mercury, as a trace heavy metal element, is one of the primary lethal pollutants due to its
30
toxicity, mobility and bioaccumulation in ecosystem and food chains [1-3]. Inorganic mercury can
31
be methylated biotically to its most toxic form, dimethyl mercury which can cause nervous system
32
disorder, kidney and liver damage, and impair childhood development [4-5]. Mercury is naturally
33
abundant in coal and heavy metal-rich geologic deposits; however, it has been largely liberated into
34
the atmosphere by human productive activities, such as natural gas exploitation, coal gasification
35
and combustion, metal sintering, gold mining and so forth [6-8]. Hence, abatement of
36
anthropogenic mercury emissions from gas streams, such as natural gas, coal-fired flue gas, syngas,
37
sintering gas, etc., has gained increasingly environmental and regulatory concern. The released
38
mercury primarily existed in three forms, i.e. elemental mercury (Hg0), oxidized mercury (Hg2+)
39
and particulate bond mercury (Hgp) [9-11]. Hg2+ species is easily absorbed by amine solution. Hgp
40
can be readily captured by baghouse, electrostatic precipitator or fabric filter. However, Hg0 is
41
hardly removed because of its high volatility and insolubility [12-14]. Therefore, efficient mercury
42
control technologies are urgently needed. Currently, there are a number of technologies available to
43
remove Hg0 from gas streams, for instance, wet advanced oxidation [15-17], catalytic oxidation
44
[18-20], photochemical oxidation [21-23], and adsorption method [24-26]. Adsorption technology,
2
45
characterized by simple equipment, convenient operation, good removing efficacy, and less
46
secondary pollution, appears to be one of the most effective pathway to remove Hg0 from gas
47
streams at low temperature. Because of its large surface area, flexible surface chemistry, and variety
48
diversity, carbon material is regarded as the most promising sorbent for mercury abatement [27-29].
49
The recent advances in Hg0 removal techniques have been summarized by some researchers.
50
Liu et al. [30] first comprehensively commented the progress of four types of advanced oxidation
51
technologies for Hg0 removal. The reaction mechanism, kinetics, reactor types and process system
52
as well as their effects on Hg0 abatement were evaluated, with insights into the challenges of
53
large-scale application. Sowlat et al. [31] systematically discussed the effects of different
54
calcinating temperatures, reaction temperatures, and flue gas components on the Hg0 removal
55
performances of cerium-modified activated carbons. Xu et al. [32] reviewed the development of
56
sorbent modification methods for Hg0 removal. The merits and shortcomings of diverse
57
modification routes, such as halide and sulfur modification, acid and alkaline impregnation, noble
58
metal and metal oxide decoration, microwave and plasma treatment, and miscellaneous
59
modification were fully discussed. Yang et al. [33] highlighted the progress in Hg0 removal by
60
gas-solid heterogeneous oxidation method from the perspective of key process parameters, reaction
61
mechanisms, and properties of catalysts or traditional sorbents. Chalkidis et al. [34] critically
62
commented the conventional and alternative sorbents as well as the processes adopted for mercury
63
abatement and remediation during natural gas processing. Liu et al. [35] discussed the advances in
64
Hg0 removal by mineral sorbents. The physiochemical features and common modification
65
approaches for various mineral materials were briefly summarized. The influencing factors and
66
possible reaction mechanisms with respect to Hg0 capture by mineral sorbents were highlighted.
3
67
However, most of these reviews mainly paid attention on conventional activated carbons,
68
metallic oxides, and mineral sorbents in perspective of processes and kinetics. Due to the rapid
69
development of material synthesis method and nanotechnology, many novel carbon-based polymers
70
or composites have been applied for Hg0 removal due to their unique physicochemical properties. In
71
this work, the research progress of Hg0 capture by novel carbon-based materials in recent five years,
72
especially emerging carbon materials, such as bio-chars, graphene and graphene oxide, carbon
73
nanotubes and nanofibers, carbon spheres, metal-organic frameworks, graphitic carbon nitrides, and
74
carbon aerogels, are reviewed. The mercury removal performances and reaction mechanisms of
75
diverse carbon-based sorbents associated with their merits and drawbacks are fully commented as
76
well.
77
2. Activated carbon
78
Activated carbon is the most widely used mercury sorbent due to the merits of high surface
79
area, favorable pore structures, and sufficient surface oxygen functional groups [36]. Raw activated
80
carbon usually shows limited Hg0 removal performance, which can be greatly enhanced by halide,
81
metal oxide, and sulfide modification [37-39].
82
Halides have been extensively employed as modifiers for activated carbon sorbents. The
83
efficiency of halogen-modified activated carbon for Hg0 removal increases in the order Cl < Br < I
84
[40]. As for metal chlorides, FeCl3 is evidenced as the most effective modifier for activated carbon
85
as compared to CuCl2, CeCl3, and MnCl2 [41]. The reaction mechanism of metal chlorides and
86
elemental mercury has been widely studied. Chen et al. [42] claimed that the cupric and chloride in
87
CuCl2-impregnated activated carbon had a cooperative effect, which significantly enhanced the Hg0
88
removal performance. Tong et al. [43] proposed that I2 was the major active sites of
4
89
KI-impregnated activated carbon for mercury removal. A high efficient I-modified activated carbon
90
was prepared via iodine vapor deposition [44]. The Hg0 capture ability of I-modified activated
91
carbon was superior to the one modified by bromide deposition. Besides, ZnCl2 in-situ activation
92
could also greatly improve the Hg0 removal efficiency of the activated carbon owing to the
93
production of ZnO [45].
94
However, halide-modified activated carbon often suffers from low thermal stability and
95
corrosion effect to the duct because of the release of halides at elevated temperatures. Therefore,
96
precious metals and transition-metal oxides had been regarded as alternative modifying reagents for
97
activated carbons due to their high thermal stability and excellent redox property. Three types of Pd
98
species were identified in Pd-loaded activated carbon, i.e. Pd0, Pd2+ and Pd2H, among which Pd0
99
was recognized as the dominant active species for Hg0 removal [46]. Presence of H2 promoted Hg0
100
adsorption attributed to PdO reduction. However, existence of H2 and O2 disfavored mercury
101
removal probably owing to the formation of inactive Pd(OH)2 and PdO, respectively. The presence
102
of PdO would decrease Pd0 content; in addition, PdO was easily sulfided by H2S. Han et al. [47]
103
pointed out that Fe addition could enhance the Hg0 removal performance of Pd-loaded activated
104
carbon. Fe2O3 could compete with PdO to react with H2S, thus protecting sorbent from H2S
105
poisoning. Au-loaded activated carbon also displayed good ability towards Hg0 adsorption due to
106
the formation of Hg-Au amalgam [48].
107
Though precious metal-modified activated carbon had good Hg0 removal performance, the
108
high capital costs and scarce sources of noble metals still restrained their large-scale application.
109
Thus, inexpensive transition-metal oxides have attracted increasing research concern recently. A
110
sequence of CeO2-MnOx modified activated carbons were used to remove Hg0 at low temperature
5
111
[49]. The existence of the Ce4+/Ce3+ redox couple and multiple valence states of Mn ions enhanced
112
the Hg0 oxidation ability of the activated carbon. CeO2-V2O5 modified activated carbons were also
113
applied for Hg0 capture at 100-200 °C [50]. V2O5 and CeO2 displayed the optimal cooperative
114
effect towards Hg0 oxidation with 1 wt% V2O5 and 8 wt% CeO2 in the sorbent. However, most
115
transition-metal oxides showed lower SO2 resistance, especially manganese oxides [51].
116
Recently, metal sulfides are considered as effective modifying reagents for activated carbons
117
due to their higher thermal stability and stronger affinities towards elemental mercury compared to
118
halides, precious metals, and transition-metal oxides. Yang et al. [52] found that copper polysulfide
119
modified activated carbon displayed better Hg0 removal performance and higher SO2 resistance
120
than those of copper or sulfur modified ones. The process of Hg0 adsorption on copper polysulfide
121
modified activated carbon is presented in Fig. 1. First, Hg0 was physically adsorbed on sorbent
122
surface. Then, the adsorbed Hg0 bonded with the active sulfur species in copper polysulfide to
123
generate stable HgS.
124 125
Fig. 1 The process of Hg0 capture from flue gas by copper polysulfide modified activated carbon
126
(AC).
127
A ZnS-modified activated carbon was attained by in-situ calcination of high sulfur-containing
128
petroleum coke and zinc nitrate under nitrogen atmosphere [53]. It sustained Hg0 removal efficiency 6
129
>84% within 360 min at or below 120 °C. But Hg0 removal was inhibited by rising reaction
130
temperature. H2S greatly enhanced Hg0 capture performance of the ZnS-modified activated carbon,
131
while H2S content had nearly no influence on Hg0 removal efficiency. Shi et al. [54] employed
132
non-thermal plasma to modify activated carbons in the presence of H2S to enhance Hg0 removal
133
performance. Sulfur content and Hg0 removal efficiency augmented with incremental H2S content.
134
The enhancement of Hg0 capture performance was due to the chemisorption rather than
135
physisorption. Hg0 was removed by binding with the sulfur species on the surface of activated
136
carbon, which yielded HgS.
137
3. Activated coke
138
Activated coke is a kind of porous carbon-based sorbent, which is not fully activated or
139
retorted as compared to activated carbon [55]. Activated coke owns higher mechanical strength,
140
better regenerability, and lower capital cost than activated carbons, making it a promising candidate
141
for mercury removal. It can also resist abrasion and crushing during circulation and handling
142
processes because of its high mechanical strength [56].
143
MnOx-CeO2 modified activated coke showed good Hg0 oxidation ability, which was plausibly
144
ascribed to the lattice oxygen and chemisorbed oxygen or hydroxyl groups on sorbent surface [57].
145
The CoOx-CeO2 modified activated coke also performed well towards Hg0 removal, which was
146
attributed to the synergetic effect between CoOx and CeO2 [58]. Zhao et al. [59] employed
147
copper-modified activated coke for Hg0 removal. Copper nitrates would decompose into CuO at
148
lower calcinating temperatures, and partially into Cu2O at higher temperatures. Furthermore, copper
149
decoration broadened the pore distribution of the activated coke, benefiting Hg0 removal. The
150
adsorbed mercury species on sorbent surface were identified as Hg0 and HgO, testifying that the
7
151
mechanism of Hg0 removal by Cu-modified activated coke was a combination of adsorption and
152
oxidation.
153
Chen et al. [60] used CoOx-CeO2 modified activated coke to simultaneously remove Hg0 and
154
HCHO. The good texture property, high dispersion of CoOx and strong redox ability contributed to
155
its good removal performances of Hg0 and HCHO. Furthermore, the interaction between CoOx and
156
CeO2 facilitated the mobility of the active oxygen species, significantly promoting the removal
157
performances of Hg0 and HCHO. Liu et al. [61] reported that MoO3-CeO2 loaded cylindrical
158
activated coke with Mo/Ce molar ratio of 1:2 performed the best towards Hg0 removal with good
159
stability and remarkable resistance to SO2 and H2O, which was attributed to the synergy effect of
160
Mo6+ and Ce3+ ions. The possible reason for its high SO2 tolerance was as follows: (i) the
161
preferential interaction between sulfate and MoO3 prevented ceria from SO2 poisoning; (ii) the
162
presence of SO2 resulted in the generation of weakly-HgO and HgSO4, appreciably promoting Hg0
163
removal. Mn-Ni co-loaded activated coke also displayed good Hg0 removal performance with
164
Mn/Ni ratio of 6:0.5. [62].
165
Semi-coke, as potentially inexpensive mercury sorbent, owns high mechanical strength,
166
well-developed pore structures, and abundant surface functional groups [63]. Fe-Ce modified lignite
167
semi-coke showed good Hg0 oxidation ability with the optimal Fe/Ce molar ratio of 0.4:0.2. H2S
168
reacting with Fe-Ce oxides yielded active sulfur, benefiting Hg0 removal via generating HgS [64].
169
However, the presence of exorbitant H2S restrained Hg0 removal, because excessive reaction of H2S
170
with Fe-Ce oxides would consume active metal oxides.
171
Zhang et al [65, 66] studied the effects of water vapor and fly ash on the Hg0 removal
172
performance of CeO2-modified semi-coke via experimental and theoretical calculation method. Hg0
8
173
removal efficiency dropped by 30% in the presence of 10% water vapor, which was probably owing
174
to the formation of Ce-OH groups and the depletion of lattice oxygen. The addition of 0.5 g fly ash
175
showed little influence on mercury removal performance. However, the Hg0 removal efficiency
176
reduced by only 15% in coexistence of water vapor and fly ash. This indicated that the production
177
of Fe-OH groups stemmed from the interaction of H2O and Fe2O3 in the fly ash reduced the
178
inhibitive effect of water steam. The effects of water vapor and fly ash on Hg0 removal over
179
CeO2-modified semi-coke is presented in Fig. 2. Fly ash slowed down the suppressive impact of
180
H2O on Hg0 removal over CeO2-modified semi-coke. Because some lattice oxygen on Fe2O3
181
surfaces was converted to highly active Fe-OH groups. The content of Fe-OH group on γ-Fe2O3
182
surface augmented faster than that of α-Fe2O3 after steam treatment, contributing to the higher Hg0
183
removal performance of γ-Fe2O3 than α-Fe2O3.
184 185
Fig. 2 The promotive mechanism of H2O on Hg0 removal over Fe2O3.
186
Petroleum coke is a waste by-product of petroleum refining process with large amounts readily
187
available worldwide. Due to its high intrinsic sulfur content, petroleum coke is regarded as an
188
attractive raw material for developing carbon-based mercury sorbent. Brominated petroleum cokes
189
had been recently employed for Hg0 removal [67, 68]. The bromine loaded on petroleum coke was
190
stable up to 200 °C. The Br-modified petroleum coke displayed excellent Hg0 removal efficiency at 9
191
100 and 200 °C. The intrinsic sulfur, primarily in the form of thiophene and organic sulfide, could
192
raise bromine depositing and increased mercury capture capacity.
193
4. Bio-char
194
Biomass, as a renewable resource, has been extensively applied in preparation of
195
carbon-based sorbents for catalytic and adsorption reactions due to its ample source, sustainability,
196
economy, and environmental benign. Bio-char, as a new kind of mercury sorbent, can be easily
197
attained via thermal pyrolysis of diverse terrestrial or marine biomass and biomass wastes, such as
198
woody and fibrous plants [69, 70], agricultural waste [71], nut waste [72], seaweed [73] and so
199
forth. After devolatilization and reconstruction of carbohydrate polymers, the resultant bio-chars
200
with loosely developed pore structures and highly active surface oxygen functional groups possess
201
excellent prospect as mercury sorbents [74].
202
4.1 Agricultural waste-derived bio-char
203
Lots of agricultural waste, such as rice straw, wheat straw, maize straw etc., can be used for
204
bio-char preparation. Cu-Ce modified bio-chars derived from rice straw demonstrated good Hg0
205
removal performance [76]. The optimal Cu/Ce molar ratio, calcination temperature, and reaction
206
temperature were 1:5, 260 °C, and 150 °C, correspondingly. Yang et al. [78] synthesized a
207
magnetic Co-Fe impregnated porous carbon stemmed from rice straw by microwave and steam
208
activation [78]. Ultrasound-assisted impregnation improved the dispersion of Co3O4 and Fe3O4 on
209
sorbent surface. While the activation of microwave and steam greatly improved the pore structures.
210
The surface chemisorbed oxygen and the lattice oxygen stemmed from Co3O4 and Fe3O4 involved
211
in Hg0 removal process. Besides, Co-Fe modified porous carbon showed good regeneration
212
performance. The plausible mechanism of Hg0 capture on Co-Fe loaded porous carbon is illustrated
10
213
in Fig. 3. The adsorbed Hg0 was oxidized into Hg2+ by high-valence Co3+ and Fe3+ ions. The
214
low-valence Co2+ and Fe2+ ions could be replenished by the oxygen from gas stream.
215 216
Fig. 3 The mechanism of Hg0 capture by Co-Fe doped porous carbon.
217
K2FeO4-modified bio-chars derived from wheat straw were developed for Hg0 removal [79].
218
K2FeO4 modification improved the pore structures and introduced new active sites, greatly
219
promoting Hg0 removal performance. Hg0 removal efficiency reduced with rising Hg0 inlet content.
220
NO facilitated Hg0 removal, because it could oxidize Hg0 into Hg(NO3)2. SO2 greatly decreased Hg0
221
removal efficiency because of the competitive adsorption between SO2 and Hg0. Yang et al. [80]
222
used a wheat straw derived bio-char modified with Mn-Ce oxides to remove Hg0 at low
223
temperature. NO and O2 improved Hg0 removal performance. Low content of steam and SO2
224
enhanced Hg0 removal, but high content of steam and SO2 restrained Hg0 removal. Magnetic Fe-Cu
225
doped bio-chars stemmed from wheat straw were employed for capturing Hg0 from flue gas [81].
226
The Fe-Cu active species, chemisorbed oxygen, and lattice oxygen on sorbent surface were
227
profitable for Hg0 removal.
228
Corn stalk derived bio-chars were treated with dielectric barrier discharge plasma to promote
229
its Hg0 adsorption capacity [82]. After plasma treatment, the surface area and pore volume reduced
11
230
subtly. While the oxygen-containing functional groups, especially C=O groups, augmented on
231
sorbent surface. The bio-chars with plasma treatment showed higher Hg0 removal efficiency than
232
that of untreated ones. The Hg0 adsorption process was probably dominated by chemisorption,
233
attributed to the highly active carbonyl and ester functional groups. Gao et al. [83] developed a
234
maize straw derived activated carbon modified with Co-Ce to simultaneously remove NO and Hg0.
235
There was a cooperative effect between Co3O4 and CeO2, leading to production of more Co3+ and
236
Ce3+ cations to induce more anionic defects and form more active oxygen and oxygen vacancies.
237
NO reduction was primarily governed by Langmuir-Hinshlwood mechanism, while Hg0 oxidation
238
related to Mars-Masson mechanism. Shan et al. [84] developed a magnetic Ce-Fe modified
239
bio-char stemmed from maize straw for elemental mercury abatement. During Hg0 removal
240
processes, Ce4+ and Fe3+ ions were reduced to Ce3+ and Fe2+ ions, respectively. The chemisorbed
241
oxygen species were significantly depleted as well.
242
Ammonium halide-modified cotton straw derived bio-chars were adopted for Hg0 removal
243
[85]. Increasing temperature could increase the mercury adsorption capacity of NH4Br and NH4I
244
modified bio-chars, whereas, high temperature would decrease the mercury adsorption capacity of
245
NH4Cl modified bio-chars. The C-X groups were identified as the dominant adsorption sites for
246
Hg0. Magnetic Mn-Fe modified cotton straw derived bio-chars performed well with respect to
247
elemental mercury abatement [86]. Microwave activation was profitable for the development of
248
pore structures. And ultrasound treatment facilitated the dispersion of Mn and Fe active
249
components.
250
To further improve the Hg0 removal performance of bio-chars. Non-thermal plasma method
251
had been adopted to introduce chlorine active sites on bio-char surface. HCl plasma activation
12
252
increased the chlorine active sites on the surface of sorghum straw derived bio-chars, contributing
253
to the significant rise in Hg0 removal efficiency [87]. X-ray absorption near edge structure
254
(XANES) analysis disclosed that the adsorbed mercury on HCl-modified bio-chars was primarily
255
presented in the form of Hg+. Hg0 vapor reacting with chlorinated active sites via electron-transfer
256
yielded Hg2Cl2. A lot of biomasses, i.e., rice straw, tobacco straw, corn straw, wheat straw, millet
257
straw, and black bean straw had been used for preparing bio-chars which were then activated with
258
Cl2 non-plasma approach [88].The number of C-Cl groups was increased after Cl2 plasma
259
treatment. The produced C-Cl groups served as active sites which enhanced Hg0 removal process.
260
The six biomasses derived bio-chars were also activated by H2S plasma, leading to the
261
remarkable increase of sulfur-containing and carboxyl groups on bio-char surface [89]. The
262
bio-chars after H2S plasma modification presented better Hg0 removal ability than unmodified ones.
263
C-S and carboxyl were recognized as the dominant functional groups producing HgS and HgO,
264
respectively. The process of Hg0 capture by H2S plasma treated bio-chars is illustrated in Fig. 4.
265
Active C-S bonds could be formed on bio-char surface after H2S plasma treatment. Active sulfur
266
species was released from the C-S bonds at high temperature and further oxidized Hg0 into HgS.
267
Besides, Hg0 could also be oxidized into HgO by the oxygen in carboxyl groups.
268 269 270
Fig. 4 Hg0 adsorption on H2S plasma activated bio-chars. A sequence of Co-doped MnOx/biomass activated carbons were developed for simultaneously
13
271
removing NO and Hg0 from flue gas [90]. Co addition increased the surface active oxygen
272
components and Mn4+ content of MnOx/biomass activated carbons. The enhancement of redox
273
ability and the strength of surface acidic sites restrained the crystallization of MnOx, possibly
274
contributing to the improvement of mercury removal performance and resistance to SO2 and H2O.
275
Xu et al. [91] prepared magnetic chlorinated bio-chars by one-step pyrolysis of Fe(NO3)3-laden
276
wood and polyvinyl chloride mixture. The Fe-Cl co-modified bio-chars displayed far better Hg0
277
removal performance than Cl-modified bio-chars. The produced Fe3O4, C-Cl bonds, and C=O
278
bonds were identified as the major active sites for Hg0 removal. The synthesis route and Hg0
279
capture process of magnetic Fe-Cl co-modified bio-chars are depicted in Fig. 5. Magnetic Fe-Cl
280
co-modified bio-chars were prepared by prolysis of Fe-laden wood and polyvinyl chloride (PVC)
281
mixture. Hg0 could be oxidized into Hg2+ by Fe3O4, C-Cl, and C=O groups.
282 283 284
Fig. 5 Synthesis and performance of magnetic Fe-Cl co-modified bio-chars. 4.2 Seaweed-derived biochar
285
The bio-chars stemmed from agricultural wastes cannot be produced on a large scale owing to
286
the geographical restriction of crop planting and limited arable lands [92]. However, ocean owns
287
huge amounts of seaweed biomass resources. The development and utilization of the seaweed
288
biomass resources, such as Sargassum, Enteromorpha, etc., could be a feasible pathway to tackle
14
289
these issues [93, 94].
290
NH4Cl- and NH4Br-modified Sargassum chars were employed for elemental mercury
291
abatement [95, 96]. Low contents of SO2 and H2O favored Hg0 removal, whereas, high contents of
292
SO2 and H2O restrained Hg0 adsorption. C-Br, C-Cl, and C=O covalent functional groups were the
293
predominant active sites. The Hg0 capture on NH4Cl- and NH4Br-modified Sargassum chars both
294
subjected to pseudo-second-order kinetic model, suggesting that Hg0 removal was controlled by
295
chemisorption process. NH4Cl- and NH4Br-modified Enteromorpha chars were also used to remove
296
Hg0 from flue gas [97]. Chlorine and bromine impregnation both promoted Hg0 adsorption. The
297
Br-modified Enteromorpha chars performed better than Cl-modified ones. The Hg0 adsorption on
298
Cl- and Br-modified Enteromorpha chars was endothermic process.
299
To avoid the release of harmful ammonia during bio-char modification process, potassium
300
halide was adopted to modify Enteromorpha chars and Sargassum chars for elemental mercury
301
abatement [98]. The Hg0 removal performances of KI-modified bio-chars were superior to KCl- and
302
KBr-modified ones. The C-I covalent groups and chemisorbed oxygen and/or weakly bonded
303
oxygen species were the dominant chemisorption sites. The application scenarios of seaweed
304
biomass are presented in Fig. 6. Bio-chars and bio-oil could be simultaneously attained by
305
high-temperature pyrolysis of seaweeds. The potassium halide-modified bio-chars were then used to
306
remove Hg0.
15
307 308
Fig. 6 The utilization of seaweed biomass for producing bio-oil and bio-chars.
309
Activated carbon was attained by pyrolysis of Sargassum and Enteromorpha associated with
310
ZnCl2 activation [99]. The Hg0 removal performances of the seaweed-derived activated carbons
311
were much better than those of the seaweed-derived chars. The optimal activation temperature was
312
800 °C. The Hg0 removal process was governed by exterior mass transfer at 80 °C and controlled
313
by chemisorption at 120 and 160 °C. The Hg0 removal process of the seaweed-derived activated
314
carbon was a combination of physisorption and chemisorption, attributed to the large specific
315
surface area and the C-Cl functional groups and active oxygen species, respectively. Though
316
seaweed-derived bio-chars have been considered as good candidates for mercury removal, the
317
harvesting cost of seaweed and large consumption of thermal energy for wet seaweed drying are the
318
major defects.
319
5. Low-dimensional carbon
320
Low dimensional carbons, as emerging carbon materials, are those own at least one physical
321
border small enough to confine electrons. This quantum confinement effect reduces the
322
dimensionality of the materials, imparting them distinct and novel properties that are not presented
323
in their bulk forms [100]. The low-dimensional carbons have also been applied for Hg0 removal in
324
recent years.
325
5.1 Graphene and graphene oxide 16
326
Graphene, known as a new member of two-dimensional carbon-based nanomaterials with a
327
single layer of sp2-hybrid carbon atoms packed into a benzenering structure, has recently aroused
328
widespread attention due to its exceptional electrical, mechanical, and thermal property [101, 102].
329
Graphene oxide possesses ample oxygen-containing functional groups, such as hydroxyl, epoxy and
330
carboxyl groups [103], which are favorable for adsorption and oxidation reactions. Therefore,
331
graphene and its derivates have been applied in many fields due to their large specific surface area,
332
fast electron transferring speed, and good mechanical strength [104].
333
Xu et al. [105, 106] prepared MnOx/graphene and Ag/graphene composites for Hg0 capture
334
at low temperature. Graphene seemed to be a perfect carrier for MnOx particles. It could be readily
335
deposited on graphene surface via hydrothermal process. Graphene also acted as electron transfer
336
channels in Hg0 oxidation reaction. Graphene facilitated the electrical conductivity of MnOx, which
337
was profitable for Hg0 oxidation reaction. Besides, MnOx/graphene and Ag/graphene both showed
338
splendid regenerative ability. Mercury as a resource could be recycled by using Ag/grapheme
339
sorbent via a facile thermal regeneration route. Though silver is a precious metal, its dosage is much
340
less than that of transition-metal oxide. Beside, the Ag-deposited graphene can be recycled after
341
heating treatment, making silver a promising modifying reagent for graphene. The synthesis route
342
of Ag/graphene and its application in Hg0 capture from flue gas is presented in Fig. 7. Graphene
343
was first synthesized using Hummers method. AgNO3 and N2H4 were then mixed together with the
344
graphene and subsequently dried and calcinated under nitrogen stream to yield Ag/graphene. The
345
Hg0 capture performance was evaluated in a horizontal a fix-bed reactor.
17
346 347
Fig. 7 The synthesis process of Ag/graphene and its application for Hg0 removal.
348
Graphene was employed to enhance the Hg0 removal performance of Mn-Ce binary metal
349
oxides [107]. The high valances of Mn4+ and Mn3+ favored Hg0 oxidation. Ceria offered abundant
350
oxygen for mercury oxidation. Graphene promoted Hg0 oxidation and adsorption process via
351
providing more reaction space and facilitating electron transfer. The field emission scanning
352
electron microscopy images of graphene oxide, MnOx@graphene oxide, and Mn-Ce@graphene
353
oxide are shown in Fig. 8. The pristine graphene oxide exhibited typical nanosheet structures. For
354
MnOx@graphene oxide, MnOx nanoparticles were evenly dispersed on the surface of graphene
355
oxide. Mn-Ce@graphene oxide presented a three-dimensional morphology with some graphene
356
oxide being covered by MnOx and CeOx grains.
357 18
358
Fig. 8 Field emission scanning electron microscopy pictures of (a) and (b) graphene oxide, (c)
359
MnOx@graphene oxide, and (d) Mn-Ce@graphene oxide.
360
Ag nanoparticles were deposited on graphene oxide for Hg0 abatement [108]. The
361
Ag/graphene oxide composite could efficiently capture Hg0 from flue gas up to 150-200 °C,
362
plausibly owing to the amalgamation of Hg0 on Ag nanoparticles. An et al. [109] reported that
363
loading Mn-Fe-Ce mixed oxides on graphene oxide could effectively remove Hg0 from flue gas at
364
170-250 °C. The Mn-Fe-Ce active components were readily dispersed on graphene surface due to
365
its large specific surface area and good mechanical property. A magnetic Ag-Fe3O4@graphene
366
oxide ternary composite was synthesized for gaseous Hg0 capture from coal-fired flue gas [110].
367
The ternary composite performed better than pristine graphene oxide and Fe3O4@graphene oxide.
368
The Hg0 was captured via Ag-Hg amalgam mechanism. The magnetic ternary composite was
369
reusable and could be possibly separated from fly ashes for multicycle utilization.
370
Apart from experimental studies, theoretical calculation method has also been applied to
371
explore the potential of graphene towards Hg0 capture and the mechanism of Hg0 adsorption on
372
graphene. Meeprasert et al. [111] studied the reactivity of single-vacancy defective graphene and
373
defective graphene-supported Pdn and Agn (n = 1, 13) towards Hg0 adsorption by using density
374
functional theory calculation method. Pdn showed higher binding ability with the defective site of
375
graphene than Agn. Metal nanocluster bonded stronger with defective graphene than single metal
376
atom. Jungsuttiwong et al. [112] studied the mechanism of Hg0 adsorption on transition-metal
377
decorated boron-doped graphene with periodic density functional theory. Pd4 type A structure
378
exhibited the highest Hg0 adsorption performance. The interaction of Hg-5d orbital and Pd-4d,
379
Pt-5d orbital contributed to its high Hg0 adsorption ability. The top view of the optimized structure
19
380
of B-doped graphene surface is presented in Fig. 9. The optimized B-doped graphene sheet
381
encompassed 12 B atoms (in red color) and 60 C atoms (in gray color). The optimal B-doped
382
graphene surface was then prepared for transition-metal atom and cluster deposition.
383 384
Fig. 9 Top view of the optimized structure of B-doped graphene in a 6 × 6 unit cells.
385
Density functional theory calculations were performed to investigate the adsorption processes
386
of mercury and arsenic on Pdn (n=1-6) decorated pyridine-like N-doped graphene [113]. The
387
vacancy site was confirmed as the most favorable adsorption site for Pd atom. The Pd atoms or
388
clusters could promote the reactivity of N-doped graphene with respect to Hg and AsH3 adsorption.
389
The capture ability of Hg on Pdn/N-doped graphene was linked to the d-band center of Pdn. The
390
closer the d-band center of Pdn to the Fermi level was, the higher adsorption strength of Hg on
391
Pdn/N-doped graphene was.
392
The adsorption processes of Hg0 on perfect, defective, and Al-doped graphene were studied
393
based on density functional theory [114]. The adsorption energies of Hg0 on perfect and defective
394
graphene were -0.220 eV and -0.342 eV, respectively, which were physisorption processes.
395
Whereas, the adsorption energy of Hg0 on Al-doped graphene was -0.570 eV, which was a
396
chemisorption process. The adsorption energy increased with increasing Al-doped vacancy sites.
397
However, the incremental Al atoms doped on a single vacancy site would reduce the adsorption
20
398
energy, which was unfavorable for Hg0 adsorption.
399
5.2 Carbon nanotube and nanofiber
400
Carbon nanotubes and nanofibers are new types of one-dimensional nanomaterials. The
401
carbon nanotubes possess perfect hexagonal connected structures, distinct thermal, electrical and
402
mechanical characteristics [115]. The carbon nanofiber features low density, large length-diameter
403
ratio, high strength, good electrical property and corrosion resistance. Furthermore, the oxygen
404
functional groups can be easily produced on the surface of carbon nanotubes and nanofibers via
405
chemical modification [116], which is conducive to Hg0 removal.
406
Mn-Mo oxides were loaded on carbon nanotubes for oxidation removal of Hg0 at low
407
temperature [117]. Mn-modified carbon nanotube displayed high Hg0 oxidation ability at 150-250
408
℃. However, it nearly lost Hg0 oxidation ability in existence of 500 ppm SO2 due to the generation
409
of MnSO4. In contrast, SO2 promoted the Hg0 oxidation ability of Mn-Mo doped carbon nanotube.
410
The probable reason was that Mo addition could facilitate the conversion of SO2 to SO3, which was
411
profitable for Hg0 oxidation. Mo species could also protect MnO2 from SO2 poisoning.
412
Fe-Ce decorated multi-walled carbon nanotube was also used for simultaneous removal of
413
Hg0 and NO from flue gas [118]. The iron-cerium hybrid oxides loaded both inside and outside of
414
the multi-walled carbon nanotube in evenly dispersion form with sizes of 3-5 nm. Some cerium
415
presented in the form of fluorite-like crystal ceria, others entered into the spinel structure of
416
γ-Fe2O3, resulting in the distortion of the γ-Fe2O3 lattice. The amounts of chemisorbed oxygen
417
species and the oxidation activities of catalysts increased remarkably after cerium addition,
418
contributing to the outstanding Hg0 and NO removal performance.
419
Dimethyl sulfoxide was adopted to modify carbon nanofibers for gas-phase Hg0 capture
21
420
[119]. Though sulfur modification reduced the surface areas and pore volumes of carbon
421
nanofibers, mercury uptake capacities augmented as compared to unmodified ones. The sulfur
422
atoms were incorporated into carbon matrix in the form of sulfides and sulfates. The sulfide groups
423
performed more effectively than sulfate groups towards Hg0 removal. Because the lone pair
424
electrons of sulfide groups acted as active sites for sulfur interacting with mercury, or at least as a
425
point of initial attachment. The micro-morphologies of pristine and sulfur-treated carbon nanofibers
426
are shown in Fig. 10. The carbonaceous species were coated on nonwoven fiber glass with diameter
427
of 5-7 μm. No sulfur clusters were observed on the surface of sulfur-treated carbon nanofibers,
428
confirming that sulfur atoms might be built-in with carbon matrix.
429 430
Fig. 10 The scanning electron microscope images of (A) pristine and (B) sulfur-treated carbon
431
nanofibers.
432
The probable mechanism of Hg0 capture by sulfur-treated carbon nanofibers is shown in Fig. 11.
433
First, Hg0 was oxidized into Hg(II) and formed a double bond with S atom via donating two pairs of
434
shared electrons. Then, one electron transferred from Hg=S double bond to C-S single bond,
435
producing active Hg and C species with one electron. Finally, the reactive electrons of Hg and C
436
species generated a single bond. The original C-S bond broke and yielded a lone pair of electrons.
22
437 438
Fig. 11 The mechanism of Hg0 adsorption on sulfur-treated carbon nanofibers.
439
Magnetic Fe-Mn oxide loaded carbon nanofibers were synthesized via one-step
440
solvothermal approach for Hg0 removal [120]. The Hg0 removal performance greatly augmented
441
with incremental Mn doping amount into Fe3O4 spinel structures. Carbon nanofiber addition
442
improved the dispersion of Fe-Mn oxide grains and promoted the electron transfer mobility, which
443
favored Hg0 removal. Mn cations and lattice or chemisorbed oxygen were regarded as active sites
444
for Hg0 oxidation. Mn-Ce oxides were supported on carbon nanofibers for Hg0 abatement [121].
445
Mn-Ce oxides were highly dispersed on carbon nanofibers and offered sufficient active components
446
for Hg0 oxidation, such as active oxygen and Mn4+ ions. The carbon nanofiber framework provided
447
channels for electron transfer during Hg0 oxidation process.
448
5.3 Carbon sphere
449
Carbon sphere, as a zero-dimensional carbon material, displays numerous advantages over
450
powder or granular activated carbon for catalyst support and adsorption process, probably owing to
451
its high surface area, excellent mobility, high compressive strength, low pressure drop, and potential
23
452
application in large-scale fluidized bed [122, 123].
453
Hierarchical α-MnO2/carbon sphere composite was fabricated via hydrothermal route for
454
Hg0 oxidation and adsorption [124]. Carbon spheres served as the core on which α-MnO2 nanorods
455
grew. The α-MnO2/carbon sphere composite performed stably with Hg0 removal efficiency of
456
>99% over 600 min on stream. Besides, it had better SO2 resistance than unsupported α-MnO2. This
457
three-dimensional α-MnO2/carbon sphere composite composed of zero-dimensional carbon sphere
458
and one-dimensional α-MnO2 was appealing for gas purification.
459
Resin-based carbon spheres were synthesized by suspension polymerization of alkyl phenol
460
and formaldehyde and steam activation in combination with surface modification by heat treatment
461
[125]. The pure carbon spheres attained via oxidation modification at 300 °C performed well,
462
probably attributed to the sufficient oxygen functional groups of C=O and C(O)-O-C. These oxygen
463
functional groups acted as strong oxidizer and promoted electron transfer for converting Hg0 to
464
Hg2+ during Hg0 chemisorption process.
465
Zhang et al. [126, 127] further modified the resin-based carbon spheres with CuO or CeO2
466
to improve its Hg0 removal ability. CuO enhanced the redox ability of the carbon sphere and was
467
profitable to activate its active species, which appreciably improved Hg0 removal performance.
468
CeO2 greatly enhanced the Hg0 removal ability of the carbon sphere through forming active species,
469
such as C=O or C-O, and lattice oxygen via Ce4+/Ce3+ redox couple for oxidizing Hg0 into HgO.
470
The micro-morphology of resin-based carbon sphere is displayed in Fig. 12. The carbon sphere
471
exhibited a relatively smooth surface with a large specific surface area of >1000 m2/g. Few pores
472
and pitted morphology were formed on the surface of the carbon sphere after steam activation.
24
473 474
Fig. 12 The scanning electron microscope image of resin-based carbon sphere.
475
The proposed mechanism for Hg0 capture on CuO-modified carbon sphere is displayed in Fig. 13.
476
Hg0 vapor was first adhered on the surface or in the pore channels of the carbon sphere. Then, it
477
was oxidized by the active components of the carbon sphere, such as C=O or C-O. Furthermore,
478
CuO would promote the activation of the active components and could also oxidize the adsorbed
479
Hg0 by itself.
480
481 482 483
Fig. 13 The mechanism of Hg0 adsorption on CuO-modified carbon sphere. 6. Carbon composite and polymer
25
484
Incorporating heteroatoms into carbon matrix can alter the electronic structures of
485
carbonaceous materials [128], which may lead to improvement in catalytic and adsorption ability.
486
Carbon bonded with metals could form metal-organic framework, which shows great potential in
487
gas separation. Carbon bonded nitrogen could produce graphitic carbon nitride, which is an
488
emerging carbon-based polymers. The metal-organic framework and graphitic carbon nitride have
489
recently been employed for Hg0 removal as well, which has become a research hotspot.
490
6.1 Metal-organic framework
491
Metal-organic frameworks, as a new class of porous materials or porous coordination
492
polymers assembled by metal ions and polyfunctional organic ligands, exhibit low density, high
493
porosity and apparent surface area, controllable pore size, well-defined structure, and chemical
494
tunability [129-132]. Since Yaghi and coworkers [133, 134] first proposed crystalline metal
495
organic frameworks, they have attracted great attention and have been applied in many fields, such
496
as hydrogen storage [135, 136], gas adsorption and separation [137, 138], catalytic reactions [139,
497
140], and environmental remediation [141, 142]. Recently, elemental mercury capture by using
498
metal-organic frameworks has gained increasing research interest due to the maturity of
499
metal-organic framework synthesis methods and the increasingly stringent regulations for mercury
500
emissions.
501
Liu et al. [143] first studied the adsorption potential of metal-organic frameworks towards
502
mercury species, i.e., Hg0, HgCl2, HgO, and HgS, by theoretical calculations based on density
503
functional theory method. The Hg0 was stably physi-sorbed on the unsaturated metal centers of
504
Mg-based metal-organic framework. The Cl endings of HgCl2 multi-interacted with two neighbored
505
Mg ions simultaneously, leading to strong adsorption strength. HgO and HgS were chemisorbed on
26
506
Mg-based metal-organic framework. Therefore, metal-organic frameworks were theoretically
507
predicted to be promising for effective removing mercury species from coal-fired flue gas.
508
Later, phenyl bromine-appended metal-organic frameworks were employed for Hg0 removal
509
[144]. Phenyl bromine was the primary chemisorption site for Hg0 capture. The optimal Br-based
510
metal-organic framework performed much better than un-functionalized metal-organic framework
511
and Br-impregnated activated carbon. The Br-based metal-organic framework showed enhanced
512
Hg0 removal efficiency in the presence of SO2, whereas steam suppressed its Hg0 removal
513
performance. The Br-based metal-organic framework showed high bromine stability during Hg0
514
adsorption, which could avoid possible bromine pollution issue often along with Br-modified
515
sorbents.
516
Mn-Ce modified metal-organic framework was also used for Hg0 and NO removal [145]. It
517
performed better than conventional Mn-Ce loaded ZrO2, especially at low temperature. The
518
metal-organic framework promoted the dispersion of active components, improved Hg0 adsorption
519
and enhanced oxygen utilization, resulting in a desirable catalytic activity. Zhao et al. [146]
520
investigated the combined effect of Ag and Zr-based metal-organic framework with respect to Hg0
521
removal. Ag addition promoted the redox activity of Zr-based metal-organic framework. Ag and
522
Zr-based metal-organic framework presented a significant cooperative effect towards Hg0 removal.
523
The plausible reaction pathways for Hg0 removal by Ag-modified Zr-based metal-organic
524
framework is illustrated in Fig. 14. At low temperature, Hg0 vapor was predominantly captured via
525
generating an Ag-Hg amalgam and channel adsorption. At high temperature, Ag transferred an
526
electron to the oxygen of C=O group to form active oxygen which then attracted an electron from
527
Hg0 through Ag. Besides, the formed active Zr combined with Hg0, which could be captured via
27
528
channel adsorption as well.
529 530
Fig. 14 The reaction pathways of Hg0 removal by Ag-modified Zr-based metal-organic framework.
531
A Cu-based metal-organic framework was adopted for Hg0 removal from sintering gas [147].
532
The Cu-based metal-organic framework showed limited Hg0 removal ability without HCl. Presence
533
of 15 ppm HCl could greatly enhanced its Hg0 removal efficiency. SO2 inhibited Hg0 removal,
534
whereas NO enhanced Hg0 adsorption. Furthermore, Cu-based metal-organic framework exhibited
535
good water-resistance. The mechanism Hg0 removal by Cu-based metal-organic framework is
536
depicted in Fig. 15. Without HCl in sintering gas, Hg0 was removed primarily by active oxygen via
537
forming HgO. With HCl in sintering gas, HCl was adsorbed on Cu-based metal-organic framework
538
to produce intermediates of CuCl or CuCl2. Hg0 was first oxidized into Hg2+ by chemisorbed
539
oxygen species. Then, the produced Hg2+ reacted with CuCl or CuCl2 to generate HgCl2.
540
Furthermore, Cl- ions may be activated by oxygen to produce active chorine species which could
541
oxidize Hg0 into HgCl2.
28
542 543
Fig. 15 The mechanism of Hg0 removal by Cu-based metal-organic framework.
544
It was reported that Cr-based metal-organic framework performed better than Cu-based and
545
Zr-based metal-organic framework [148]. Hg0 removal efficiency augmented with the increasing
546
reaction temperature and oxygen content. The open metal site of Cr-based metal-organic framework
547
was the key factor for Hg0 removal. Hg0 was first adsorbed on Cr-based metal-organic framework
548
and then oxidized into Hg2+ by the open metal site Cr3+. The yielding Hg2+ subsequently reacted
549
with chemisorbed oxygen to produce HgO. While the reduced open metal site Cr2+ was reoxidized
550
into Cr3+ by surface active oxygen. However, high-valence chromium is harmful to human health,
551
which might limit its further application.
552
Zhou et al. [149] loaded α-MnO2 onto Al-based metal-organic framework for Hg0 removal.
553
Al-based metal-organic framework could expose more active sites of α-MnO2, contributing to the
554
enhancement in the Hg0 oxidation ability of α-MnO2. A Se-functionalized metal-organic framework
555
was synthesized for Hg0 removal [150]. The Se-based metal-organic framework displayed a
556
distinguished mercury adsorption capacity of 148.19 mg/g which was about 154 to 705 times bigger
557
than that of commercial activated carbons. Besides, its prominent mercury adsorption stability could
558
still retain under simulated flue gas atmosphere. The gas-phase Hg0 was oxidized into stable and
559
water-insoluble HgSe, ensuring the minimal re-emission or even sequestration of mercury. 29
560
However, the scarcity and toxicity of selenium might be an obstruction for its practical application.
561
6.3 Graphitic carbon nitride
562
Graphitic carbon nitride (g-C3N4), the most stable allotrope of polymeric carbon nitride, has
563
attracted increasing attention due to the facile synthesis route, abundant sources, high thermal and
564
chemical stability, environmentally benign and good biocompatibility, and distinctive electronic
565
structure [151-154]. These unique properties allow for its diverse applications, such as
566
photocatalytic hydrogen evolution [155], wastewater decontamination [156], nitric oxide removal
567
[157], and carbon dioxide reduction [158]. Recently, Liu et al. [159] first explored the potential of
568
g-C3N4 for Hg0 adsorption. They found that g-C3N4 exhibited strong affinity with Hg0. Precursors
569
had a big impact on Hg0 removal performance. The g-C3N4 stemmed from urea high-temperature
570
polymerization displayed a striking Hg0 capture ability with Hg0 removal efficiency of ~84%,
571
which was significantly higher than those of dicyandiamide- and melamine-derived g-C3N4. The
572
probable reason was that the specific surface area of the urea-derived g-C3N4 was much bigger than
573
those of the dicyandiamide- and melamine-derived g-C3N4.
574
CuO/g-C3N4 nanocomposites were prepared via incipient-wetness impregnation method for
575
elemental mercury abatement [160]. Pristine g-C3N4 was attained via a two-step calcinating
576
approach. g-C3N4 displayed good Hg0 adsorption performance at 40-200 °C. CuO decoration
577
greatly enhanced the Hg0 removal ability of g-C3N4 owing to the close interaction of CuO and
578
g-C3N4. Liu et al. [161] fabricated a porous g-C3N4 via a facile two-step thermal etching oxidation
579
method for Hg0 removal. The porous g-C3N4 also displayed good reactivity towards Hg0 adsorption
580
at 40-200 °C. CuO decoration efficiently activated g-C3N4, imparting it enhanced Hg0 oxidation
581
ability due to the Mott-Schottky effect at the interface of CuO and g-C3N4.
30
582
It is well established that g-C3N4 nanosheet owns big surface area for exposing plentiful
583
active sites and short bulk diffusion length for promoting electron transfer, which are conducive to
584
adsorption and catalytic reactions [162, 163]. A two-dimensional g-C3N4 nanosheet was synthesized
585
via thermal exfoliation of bulk g-C3N4 [164, 165]. The g-C3N4 nanosheet performed well with
586
respect to Hg0 removal at 60-240 °C. The maximal Hg0 removal efficiency of ~65.8% was reached
587
at 150 °C due to the two-dimensional planar structure and big specific surface area of g-C3N4
588
nanosheet. The transmission electron microscopy photo of g-C3N4 nanosheet is shown in Fig. 16.
589
The pristine g-C3N4 nanosheet displayed ultrathin sheet-like morphology with thickness of ~1-10
590
nm and lateral size of ~1-3 µm. The specific surface area of the g-C3N4 nanosheet was ~109 m2/g.
591 592
Fig. 16 The transmission electron microscopy image of g-C3N4 nanosheet.
593
MnO2 and Co3O4 decoration significantly enhanced the Hg0 removal performance of the
594
g-C3N4 nanosheet. The plausible reason was attributed to the excellent redox abilities of MnO2 and
595
Co3O4 and the enhanced electron mobility at the interface of MnO2 or Co3O4 and g-C3N4.
596
MnO2-decorated g-C3N4 nanosheet displayed Hg0 removal efficiency all above 91% within 90-240
597
°C. Co3O4-modified g-C3N4 nanosheet presented excellent Hg0 capture ability with Hg0 removal
598
efficiency of ~100% within 120-240 °C. However, NO and SO2 significantly inhibited the Hg0
599
removal performance of the Co3O4-modified g-C3N4 nanosheet, probably due to the competitive 31
600
adsorption and side reactions. The mechanism of Hg0 removal over MnO2-modified g-C3N4
601
nanosheet is depicted in Fig. 17. The gas-phase Hg0 was oxidized into HgO by surface active
602
oxygen (Oad) and lattice oxygen ([O]) of MnO2 which was reduced to Mn2O3. Gaseous O2
603
replenished the depleted chemisorbed oxygen and lattice oxygen and simultaneously oxidized
604
Mn2O3 into MnO2 to refresh the active component for Hg0 oxidation.
605 606
Fig. 17 The process of Hg0 oxidation by MnO2-loaded g-C3N4 nanosheet.
607
In addition, Liu et al. [166] first employed CuCl2-loaded carbon aerogels for elemental
608
mercury removal at low temperature. It displayed very stable Hg0 removal performance with
609
~100% Hg0 removal efficiency over 600 min on stream. To further lower down the capital cost of
610
carbon aerogel, a seaweed-templated pathway was developed for controllable synthesis of
611
SnO2-loaded carbon aerogels to simultaneously remove Hg0 and H2S [167]. The carbon aerogels
612
possess distinct three-dimensional network structures. The nanoconfinement of carbon nanoshells
613
could prevent the growth and agglomeration of SnO2 nanoparticles during regeneration process,
614
which favored removal of Hg0 and H2S [168-170]. The three-dimensional interconnected macro-
615
and meso-pores of carbon aerogels was conducive to Hg0 and H2S removal at high space velocities.
32
616
Carbon aerogel might also be a potential carbon-based sorbent for Hg0 removal provided the capital
617
cost is reduced and synthesis process is simplified. In addition, some practical industrial gas streams
618
are extremely complex, and often simultaneously contain multiple gas components such as H2O,
619
NOx, HCl, H2S, SO2, CO, SO3, VOCs, etc [171-180]. Thus much more work should be conducted
620
to further improve the stability of these carbon-based adsorbents in the presence of H2O, NOx, HCl,
621
H2S, SO2, CO, SO3, VOCs, etc., and reveal the effects of these gas components on Hg0 removal.
622
7. Conclusions and prospects
623
Atmospheric mercury pollution has become a global concern mainly due to the large
624
consumption of fossil fuels and gold mining. The primary challenge for reducing elemental mercury
625
from gas streams is to search for environmentally benign, inexpensive, regenerable, and efficient
626
mercury sorbents with good resistance to NO, SO2, and H2O. Carbon-based materials are deemed to
627
be appealing candidates for removing Hg0 from gas streams at low temperature. This review
628
provided the state-of-the-art of carbon-based sorbents for elemental mercury abatement in the view
629
point of material and chemistry. To date, massive carbon materials have been employed for Hg0
630
capture. The advantages and disadvantages of versatile carbon-based materials towards elemental
631
mercury removal are summarized as follows.
632
Activated carbon is the only commercialized mercury sorbent due to its wealthy pore
633
structure and sufficient surface oxygen functional groups. Activated carbon injection technology
634
has been widely applied in coal-fired power plants. However, the high operation cost and
635
detrimental effect on fly ash utilization hampered its industrial application. Activated coke,
636
including semi-coke and petroleum coke, could be alternatives to the activated carbon because of its
637
higher mechanical strength, better regenerability, and lower capital cost. Ongoing and future efforts
33
638
should pay more attention on how to improve its reusability and efficiency. Combing magnetic
639
metal oxides with activated coke is a feasible pathway to tackle this issue.
640
Bio-chars, obtained from direct pyrolysis of diverse terrestrial or marine biomass and biomass
641
wastes at high temperature, are regarded as sustainable and inexpensive mercury sorbents. So far,
642
bio-chars have been extensively investigated for elemental mercury removal owing to their
643
sustainability and sufficient sources. However, virgin bio-chars display fairly low surface area and
644
poor activity towards Hg0 adsorption. In situ activation can greatly improve the porosity and surface
645
area of the bio-chars, and thereby strengthening Hg0 removal performance. Besides, appropriate
646
modification methods, e.g., green, efficient, and inexpensive, associating with high removing
647
efficiency and less contamination to the environment, plays a pivotal role in the large-scale
648
application of bio-chars.
649
Low-dimensional carbons own good electronic conductivity and excellent electron transfer
650
mobility, making them good mercury sorbents after loading with active components. However, the
651
synthesis routes for most low-dimensional carbons, particularly graphene, are time consuming and
652
energy consumption, leading to high capital costs of the low-dimensional carbons. Furthermore, the
653
low activities of pristine low-dimensional carbons restrained their practical utilizations.
654
Metal-organic frameworks are characterized by tunable chemical properties and porous structures
655
through altering their carbonaceous ligands. Some research works showed that metal and halogen
656
modified metal-organic frameworks displayed good Hg0 removal performance. Nevertheless, the
657
high cost and sensitivity towards steam and acidic and basic gases restricted their large-scale
658
application. Thus, the development of low-dimensional carbon and metal-organic framework
659
sorbents highly depend on the progress in material science and engineering. The development of
34
660
new synthetic processes with low cost and simple operation and recyclable characteristics of
661
sorbents are the key factors in the further development of low-dimensional carbon and
662
metal-organic framework mercury sorbents.
663
Graphitic carbon nitride is a new kind of carbon-based sorbent for elemental mercury
664
abatement from coal-derived flue gas. Recent experimental studies found that g-C3N4 performed
665
effectively towards Hg0 adsorption at low temperature. The strong affinity of g-C3N4 with Hg0 is
666
plausibly attributed to its unique electronic characteristics and layered structure. Besides, g-C3N4
667
features high thermal and chemical stability and can be facilely attained from diverse sources. Thus,
668
g-C3N4 shows appealing prospect as novel carbon-based sorbents for Hg0 removal. However, the
669
performance of g-C3N4 is significantly affected by gas components. Some practical industrial gas
670
streams are extremely complex, and often simultaneously contain multiple gas components such as
671
H2O, NOx, HCl, H2S, SO2, CO, SO3, VOCs, etc. Thus much more work should be conducted to
672
further improve the stability of these carbon-based adsorbents in the presence of H2O, NOx, HCl,
673
H2S, SO2, CO, SO3, VOCs, etc., and reveal the effects of these gas components on Hg0 removal.
674
Furthermore, the disposal of spent sorbents after mercury capture also plays an important role in
675
mercury emission control by adsorption technique. Generally, the spent sorbents can be regenerated
676
and reused after heating treatment at middle temperature under nitrogen stream.
677
Acknowledgements
678
This work is supported by the National Natural Science Foundation of China (51576094;
679
U1710108), and the Senior Talent Foundation of Jiangsu University (18JDG017).
680
References
681
[1] Reddy BM, Durgasri N, Kumar TV, Bhargava SK (2012) Abatement of gas-phase mercury-recent
682
developments. Catal Rev 54: 344-398. 35
683
[2] Li H, Wu C, Li Y, Li L, Zhang J (2012) Role of flue gas components on mercury oxidation over TiO2
684
Supported MnOx-CeO2 mixed-oxide at low temperature. J Hazard Mater 243: 117-123.
685
[3] Liu YX, Zhang J, Yin Y (2014) Study on absorption of elemental mercury from flue gas by UV/H2O2: Process
686
parameters and reaction mechanism. Chem Eng J 249: 72-78.
687
[4] Jampaiah D, Ippolito SJ, Sabri YM, Reddy BM, Bhargava SK (2015) Highly efficient nanosized Mn and Fe
688
co-doped ceria-based solid solutions for elemental mercury removal at low flue gas temperatures. Catal Sci
689
Technol 5: 2913-2924.
690
[5] Jampaiah D, Ippolito SJ, Sabri YM, Tardio J, Selvakannan PR, Nafady A, Reddy BM, Bhargava SK (2016)
691
Ceria-zirconia modified MnOx catalysts for gaseous elemental mercury oxidation and adsorption. Catal. Sci.
692
Technol. 6: 1792-1803.
693
[6] Pacyna EG, Pacyna J, Sundseth K, Munthe J, Kindbom K, Wilson S, Steenhuisen
694
Global emission of mercury to the atmosphere from anthropogenic sources in 2005 and projections to 2020.
695
Atmos. Environ. 44: 2487-2499.
696
[7] Krabbenhoft DP, Sunderland EM (2013) Global change and mercury. Science 341: 1457-1458.
697
[8] Wang Y, Xu H, Liu YX (2019) Oxidative absorption of elemental mercury from flue gas using modified
698
Fenton-like wet scrubbing system. Energy Fuels 33: 3208-3033.
699
[9] Wang SX, Zhang L, Li GH, Wu Y, Hao JM, Pirrone N, Sprovieri F, Ancora MP (2010) Mercury emission and
700
speciation of coal-fired power plants in China. Atmos. Chem. Phys. 10: 1183-1192.
701
[10] Liu YX, Zhang J, Pan J (2014) Photochemical oxidation removal of Hg0 from flue gas containing SO2/NO by
702
ultraviolet irradiation/hydrogen peroxide (UV/H2O2) process. Energy Fuels 28: 2135-2143.
703
[11] Liu YX, Li Y, Xu H, Xu J (2019) Oxidation removal of gaseous Hg0 using enhanced-Fenton system in a
704
bubble column reactor. Fuel 246: 358-364.
705
[12] Liu YX, Wang Y, Wang Q, Pan J, Zhang Y, Zhang J (2015) A study on removal of elemental mercury in flue
706
gas using Fenton solution. J Hazard Mater 292: 164-172.
707
[13] Liu YX, Zhou J, Zhang Y, Pan J, Wang Q, Zhang J (2015) Removal of Hg0 and simultaneous removal of
36
F, Maxson P (2010)
708
Hg0/SO2/NO in flue gas using two Fenton-like reagents in a spray reactor. Fuel 145: 180-188.
709
[14] Liu YX, Wang Q (2014) Removal of elemental mercury from flue gas by thermally activated ammonium
710
persulfate in a bubble column reactor. Environ Sci Technol 48: 12181-12189.
711
[15] Liu YX, Wang, Y (2019) Gaseous elemental mercury removal using VUV and heat coactivation of
712
oxone/H2O/O2 in a VUV-spraying reactor. Fuel 243: 352-361.
713
[16] Liu YX, Wang Y (2018) Elemental mercury removal from flue gas using heat and Co2+/Fe2+ coactivated
714
oxone oxidation system. Chem Eng J 348: 464-475.
715
[17] Liu YX, Wang Y (2018) Removal of Hg0 from simulated flue gas by ultraviolet light/heat/persulfate process
716
in an UV-impinging stream reactor. Energy Fuels 32: 12416-12425.
717
[18] Li H, Wu S, Wu CY, Wang J, Li L, Shih K (2015) SCR atmosphere induced reduction of oxidized mercury
718
over CuO-CeO2/TiO2 catalyst. Environ Sci Technol 49: 7373-7379.
719
[19] Li J, Yan N, Qu Z, Qiao S, Yang S, Liu P, Jia J (2010) Catalytic oxidation of elemental mercury over the
720
modified catalyst Mn/α-Al2O3 at lower temperatures. Environ Sci Technol 44: 426-431.
721
[20] Zhao L, Li C, Wang Y, Wu H, Gao L, Zhang J, Zeng G (2016) Simultaneous removal of elemental mercury
722
and NO from simulated flue gas using a CeO2 modified V2O5-WO3/TiO2 catalyst. Catal Sci Technol 7:
723
1745-2010.
724
[21] Wu J, Li C, Zhao X, Wu Q, Qi X, Chen X, Hu T, Cao Y (2015) Photocatalytic oxidation of gas-phase Hg0 by
725
CuO/TiO2. Appl Catal B-Environ 176: 559-569.
726
[22] Sun X, Wu J, Liu Q, Tian F (2018) Mechanism insights into the enhanced activity and stability of
727
hierarchical bismuth oxyiodide microspheres with selectively exposed (001) or (110) facets for photocatalytic
728
oxidation of gaseous mercury. Appl Surf Sci 455: 864-875.
729
[23] Patiphatpanya P, Phuruangrat A, Thongtem S, Thongtem T (2017) Microwave-assisted synthesis and
730
characterization of BiOIO3 nanoplates for photocatalysis. Mater Lett 209: 264-267.
731
[24] Liu DJ, Zhou WG, Wu J (2017) Effect of Ce and La on the activity of CuO/ZSM-5 and MnOx/ZSM-5
37
732
composites for elemental mercury removal at low temperature. Fuel 194: 115-122.
733
[25] Yang W, Hussain A, Zhang J, Liu YX (2018) Removal of elemental mercury from flue gas using red mud
734
impregnated by KBr and KI reagent. Chem Eng J 341: 483–494.
735
[26] Liu DJ, Zhou WG, Wu J (2019) Kinetic behavior of elemental mercury sorption on cerium- and
736
lanthanum-based composite oxides. Surf Rev Lett 26: 1850141.
737
[27] Li G, Wu Q, Wang S, Li Z, Liang H, Tang Y, Zhao M, Chen L, Liu K, Wang F (2017) The influence of flue
738
gas components and activated carbon injection on mercury capture of municipal solid waste incineration in China.
739
Chem Eng J 326: 561-569.
740
[28] Sun P, Zhang B, Zeng X, Luo G, Li X, Yao H, Zheng C (2017) Deep study on effects of activated carbon’s
741
oxygen functional groups. Fuel 200: 100-106.
742
[29] De M, Azargohar R, Dalai AK, Shewchuk SR (2013) Mercury removal by bio-char based modified activated
743
carbons. Fuel 103: 570-578.
744
[30] Liu YX, Adewuyi YG (2016) A review on removal of elemental mercury from flue gas using advanced
745
oxidation process: Chemistry and process. Chem Eng Res Des 112: 199-250.
746
[31] Sowlat MH, Kakavandi B, Lotfi S, Yunesian M, Abdollahi M, Kalantary RR (2017) A systematic review on
747
the efficiency of cerium-impregnated activated carbons for the removal of gas-phase, elemental mercury from flue
748
gas. Environ Sci Pollut Res 24: 12092-12103.
749
[32] Xu W, Hussain A, Liu YX (2018) A Review on modification methods of adsorbents for elemental mercury
750
from flue gas. Chem Eng J 346: 692-711.
751
[33] Yang W, Adewuyi YG, Hussain A, Liu YX (2019) Recent developments on gas-solid heterogeneous
752
oxidation removal of elemental mercury from flue gas. Environ Chem Lett 17: 19-47.
753
[34] Chalkidis A, Jampaiah D, Hartley PG, Sabri YM, Bhargava SK (2020) Mercury in natural gas streams: A
754
review of materials and processes for abatement and remediation. J Hazard Mater 382: 121036.
755
[35] Liu H, Chang L, Liu W, Xiong Z, Zhao Y, Zhang J (2020) Advances in mercury removal from coal-fired flue
38
756
gas by mineral adsorbents. Chem Eng J 379: 122263.
757
[36] Fan L, Ling L, Wang B, Zhang R (2016) The adsorption of mercury species and catalytic oxidation of Hg0 on
758
the metal-loaded activated carbon. Appl Catal A-Gen 520: 13-23.
759
[37] Sano A, Takaoka M, Shiota K (2017) Vapor-phase elemental mercury adsorption by activated carbon
760
co-impregnated with sulfur and chlorine. Chem Eng J 315: 598-607.
761
[38] Wang Y, Li C, Zhao L, Xie Y, Zhang X, Zeng G, Wu H, Zhang J (2016) Study on the removal of elemental
762
mercury from simulated flue gas by Fe2O3-CeO2/AC at low temperature. Environ Sci Pollut Res 23: 5099-5110.
763
[39] Ie I, Hung C, Jen Y, Yuan C, Chen W (2013) Adsorption of vapor-phase elemental mercury (Hg0) and
764
mercury chloride (HgCl2) with innovative composite activated carbons impregnated with Na2S and S0 in different
765
sequences. Chem Eng J 229: 469-476.
766
[40] Rungnim C Promarak V, Hannongbua S, Kungwan N, Namuangruk, S (2016) Complete reaction
767
mechanisms of mercury oxidation on halogenated activated carbon. J Hazard Mater 310: 253-260.
768
[41] Wang X, Wang L, Bian Z, Ning P, Wang P, Wang F, Ma Y (2018) Adsorption of gaseous elemental mercury
769
by ferric chloride-modified activated carbon under low temperature conditions. Clean-Soil Air Water 46:1800351.
770
[42] Chen Y, Guo X, Wu F, Huang Y, Yin Z (2018) Experimental and theoretical studies for the mechanism of
771
mercury oxidation over chlorine and cupric impregnated activated carbon. Appl Surf Sci 458: 790-799.
772
[43] Tong L, Yue T, Zuo P, Zhang X, Wang C, Gao J, Wang K (2017) Effect of characteristics of KI-impregnated
773
activated carbon and flue gas components on Hg0 removal. Fuel 197: 1-7.
774
[44] Zhong L, Li W, Zhang Y, Norris P, Cao Y, Pan W (2017) Kinetic studies of mercury adsorption in activated
775
carbon modified by iodine steam vapor deposition method. Fuel 188: 343-351.
776
[45] Hong D, Zhou J, Hu C, Zhou Q, Mao J, Qin Q (2019) Mercury removal mechanism of AC prepared by
777
one-step activation with ZnCl2. Fuel 235: 326-335.
39
778
[46] Yue C, Wang J, Han L, Chang L, Hu Y, Wang H (2015) Effects of pretreatment of Pd/AC sorbents on the
779
removal of Hg0 from coal derived fuel gas. Fuel Process Technol 135: 125-132.
780
[47] Han L, He X, Yue C, Hu Y, Li L, Chang L, Wang H, Wang J (2016) Fe doping Pd/AC sorbent efficiently
781
improving the Hg0 removal from the coal-derived fuel gas. Fuel 182: 64-72.
782
[48] Gómez-Giménez C, Izquierdo MT, Obras-Loscertales M, Diego LF, García-Labiano F, Adánez J (2017)
783
Mercury capture by a structured Au/C regenerable sorbent under oxycoal combustion representative and real
784
conditions. Fuel 207: 821-829.
785
[49] Wu J, Zhao Z, Huang T, Zhang J, Tian H, Zhao X, Zhao L, He P, Gao K (2017) Removal of elemental
786
mercury by Ce-Mn co-modified activated carbon catalyst. Catal Commun 93: 62-66.
787
[50] Zhu Y, Han X, Huang Z, Hou Y, Guo Y, Wu M (2018) Superior activity of CeO2 modified V2O5/AC catalyst
788
for mercury removal at low temperature. Chem Eng J 337: 741-749.
789
[51] Xie J, Xu H, Qu Z, Huang W, Chen W, Ma Y, Zhao S, Liu P, Yan N (2014) Sn-Mn binary metal oxides as
790
non-carbon sorbent for mercury removal in a wide-temperature window. J Colloid Interf Sci 428: 121-127.
791
[52] Yang S, Wang D, Liu H, Liu G, Xie X, Xu Z, Liu Z (2019) Highly stable activated carbon composite
792
material to selectively capture gas phase elemental mercury from smelting flue gas: Copper polysulfide
793
modification. Chem Eng J 358: 1235-1242.
794
[53] Huo Q, Wang Y, Chen H, Han L, Wang J, Bao W, Chang L, Xie K (2019) ZnS/AC sorbent derived from the
795
high sulfur petroleum coke for mercury removal. Fuel Process Technol 191: 36-43.
796
[54] Shi M, Luo G, Xu Y, Zou R, Zhu H, Hu J, Li X, Yao H (2019) Using H2S plasma to modify activated carbon
797
for elemental mercury removal. Fuel 254: 115549.
798
[55] Ma J, Li C, Zhao L, Zhang J, Zeng G, Zhang X, Xie Y (2015) Study on removal of elemental mercury from
799
simulated flue gas over activated coke treated by acid. Appl Surf Sci 329: 292-300.
40
800
[56] Tao S, Li C, Fan X, Zeng G, Lu P, Zhang X, Wen Q, Zhao W, Luo D, Fan C (2012) Activated coke
801
impregnated with cerium chloride used for elemental mercury removal from simulated flue gas. Chem Eng J 201:
802
547-556.
803
[57] Xie Y, Li C, Zhao L, Zhang J, Zeng G, Zhang X, Zhang W, Tao S (2015) Experimental study on Hg0
804
removal from flue gas over columnar MnOx-CeO2 activated coke. Appl Surf Sci 333: 59-67.
805
[58] Wu H, Li C, Zhao L, Zhang J, Zeng G, Xie Y, Zhang X, Wang Y (2015) Removal of gaseous elemental
806
mercury by cylindrical activated coke loaded with CoOx-CeO2 from simulated coal combustion flue gas. Energy
807
Fuels 29: 6747-6757.
808
[59] Zhao B, Yi H, Tang X, Li Q, Liu D, Gao F (2016) Copper modified activated coke for mercury removal from
809
coal-fired flue gas. Chem Eng J 286: 585-593.
810
[60] Chen J, Li C, Li S, Lu P, Gao L, Du X, Yi Y (2018) Simultaneous removal of HCHO and elemental mercury
811
from flue gas over Co-Ce oxides supported on activated coke impregnated by sulfuric acid. Chem Eng J 338:
812
358-368.
813
[61] Liu M, Li C, Zeng Q, Du X, Gao L, Li S, Zhai Y (2019) Study on removal of elemental mercury over
814
MoO3-CeO2/cylindrical activated coke in the presence of SO2 by Hg-temperature-programmed desorption. Chem
815
Eng J 371: 666-678.
816
[62] Zeng Q, Li C, Li S, Liu M, Du X, Gao L, Zhai Y (2019) Adsorption and oxidation of elemental mercury from
817
coal-fired flue gas over activated coke loaded with Mn-Ni oxides. Environ Sci Pollut Res 26: 15420-15435.
818
[63] Zhang H, Chen J, Zhao K, Niu Q, Wang L (2016) Removal of vapor-phase elemental mercury from
819
simulated syngas using semi-coke modified by Mn/Ce doping. J Fuel Chem Technol 44: 394-400.
820
[64] Zhang X, Dong Y, Cui L, An D, Feng Y (2018) Removal of elemental mercury from coal pyrolysis gas using
821
Fe-Ce oxides supported on lignite semi-coke modified by the hydrothermal impregnation method. Energy Fuels
41
822
32: 12861-12870.
823
[65] Zhang H, Zhao K, Gao Y, Tian Y, Liang P (2017) Inhibitory effects of water vapor on elemental mercury
824
removal performance over cerium-oxide-modified semi-coke. Chem Eng J 324: 279-286.
825
[66] Zhang H, Sun H, Zhao K, Han Y, Wu J, Jiao T, Liang P (2018) Influences of water vapor and fly ash on
826
elemental mercury removal over cerium-oxide-modified semi-coke. Fuel 217: 211-217.
827
[67] Xiao Y, Pudasainee D, Gupta R, Xu Z, Diao Y (2017) Elemental mercury reaction chemistry on brominated
828
petroleum cokes. Carbon 124: 89-96.
829
[68] Xiao Y, Pudasainee D, Gupta R, Xu Z, Diao Y (2017) Bromination of petroleum coke for elemental mercury
830
capture. J Hazard Mater 336: 232-239.
831
[69] Xu Y, Zeng X, Luo G, Zhang B, Xu P, Xu M, Yao H (2016) Chlorine-Char composite synthesized by
832
co-pyrolysis of biomass wastes and polyvinyl chloride for elemental mercury removal. Fuel 183: 73-79.
833
[70] Xu H, Shen B, Yuan P, Lu F, Tian L, Zhang X (2016) The adsorption mechanism of elemental mercury by
834
HNO3-modified bamboo char. Fuel Process Technol 154: 139-146.
835
[71] Shu T, Lu P, He N (2013) Mercury adsorption of modified mulberry twig chars in a simulated flue gas.
836
Bioresource Technol 136: 182-187.
837
[72] Zeng J, Li C, Zhao L, Gao L, Du X, Zhang J, Tang L, Zeng G (2017) Removal of elemental mercury from
838
simulated flue gas over peanut shells carbon loaded with iodine ions, manganese oxides, and zirconium dioxide.
839
Energy Fuels 31: 13909-13920.
840
[73] Hu Y, Wang S, Wang Q, He Z, Lin X, Xu S, Ji H, Li Y (2017) Effect of different pretreatments on the
841
thermal degradation of seaweed biomass. P Combust Inst 36: 2271-2281.
842
[74] Mosier N, Wyman C, Dale B, Elander R, Lee YY, Ladisch M (2005) Features of promising technologies for
843
pretreatment of lignocellulosic biomass. Bioresource Technol 96: 673-686.
844
[75] Zhu C, Duan Y, Wu C, Zhou Q, She M, Yao T, Zhang J (2016) Mercury removal and synergistic capture of
845
SO2/NO by ammonium halides modified rice husk char. Fuel 172: 160-169. 42
846
[76] Xu W, Adewuyi YG, Liu YX (2018) Removal of elemental mercury from flue gas using CuOx and CeO2
847
modified rice straw chars enhanced by ultrasound. Fuel Process Technol 170: 21-31.
848
[77] Yang R, Diao Y, Abayneh B (2018) Removal of Hg0 from simulated flue gas over silver-loaded rice husk
849
gasification char. R Soc Open Sci 5: 180248.
850
[78] Yang W, Chen H, Han X, Ding S, Shan Y, Liu YX (2020) Preparation of magnetic Co-Fe modified porous
851
carbon from agricultural wastes by microwave and steam activation for mercury removal. J Hazard Mater 381:
852
120981.
853
[79] Zhou J, Liu YX, Pan J (2017) Removal of elemental mercury from flue gas using wheat straw chars modified
854
by K2FeO4 reagent. Environ Technol 38: 3047-3054.
855
[80] Yang W, Liu YX, Wang Q, Pan J (2017) Removal of elemental mercury from flue gas using wheat straw
856
chars modified by Mn-Ce mixed oxides with ultrasonic-assisted impregnation. Chem Eng J 326: 169-181.
857
[81] Yang W, Li Y, Shi S, Chen H, Shan Y, Liu YX (2019) Mercury removal from flue gas by magnetic
858
iron-copper oxide modified porous char derived from biomass materials. Fuel 256: 115977.
859
[82] Niu Q, Luo J, Xia Y, Sun S, Chen Q (2017) Surface modification of bio-char by dielectric barrier discharge
860
plasma for Hg0 removal. Fuel Process Technol 156: 310-316.
861
[83] Gao L, Li C, Zhang J, Du X, Li S, Zeng J, Yi Y, Zeng G (2018) Simultaneous removal of NO and Hg0 from
862
simulated flue gas over CoOx-CeO2 loaded biomass activated carbon derived from maize straw at low
863
temperatures. Chem Eng J 342: 339-349.
864
[84] Shan Y, Yang W, Li Y, Chen H, Liu YX (2019) Removal of elemental mercury from flue gas using
865
microwave/ultrasound-activated Ce-Fe magnetic porous carbon derived from biomass straw. Energy Fuels 33:
866
8394-8402.
867
[85] Li G, Wang S, Wang F, Shen B (2017) Mechanism identification of temperature influence on mercury
868
adsorption capacity of different halides modified bio-chars. Chem Eng J 315: 251-261.
869
[86] Shan Y, Yang W, Li Y, Liu YX, Pan J (2019) Preparation of microwave-activated magnetic bio-char
870
adsorbent and study on removal of elemental mercury from flue gas. Sci Total Environ 697: 134049.
871
[87] Luo J, Jin M, Ye L, Cao Y, Yan Y, Du R, Yoshiie, R, Ueki Y, Naruse I, Lin C, Lee Y (2019) Removal of
872
gaseous elemental mercury by hydrogen chloride non-thermal plasma modified biochar. J Hazard Mater 377:
873
132-141.
43
874
[88] Wang T, Liu J, Zhang Y, Zhang H, Chen W, Norris P, Pan W (2018) Use of a non-thermal plasma technique
875
to increase the number of chlorine active sites on biochar for improved mercury removal. Chem Eng J 331:
876
536-544.
877
[89] Zhang H, Wang T, Sui Z, Zhang Y, Sun B, Pan W (2019) Enhanced mercury removal by transplanting
878
sulfur-containing functional groups to biochar through plasma. Fuel 253: 703-712.
879
[90] Gao L, Li C, Li S, Zhang W, Du X, Huang L, Zhu Y, Zhai Y, Zeng G (2019) Superior performance and
880
resistance to SO2 and H2O over CoOx-modifed MnOx/biomass activated carbons for simultaneous Hg0 and NO
881
removal. Chem Eng J 371: 781-795.
882
[91] Xu Y, Luo G, He S, Deng F, Pang Q, Xu Y, Yao H (2019) Efficient removal of elemental mercury by
883
magnetic chlorinated biochars derived from co-pyrolysis of Fe(NO3)3-laden wood and polyvinyl chloride waste.
884
Fuel 239: 982-990.
885
[92] Maddi B, Viamajala S, Varanasi S (2011) Comparative study of pyrolysis of algal biomass from natural lake
886
blooms with lignocellulosic biomass. Bioresource Technol 102: 11018-11026.
887
[93] Ding S, Liu YX (2020) Adsorption of CO2 from flue gas by novel seaweed-based KOH-activated porous
888
biochars. Fuel 260: 116382.
889
[94] Wang S, Xia Z, Hu Y, He Z, Uzoejinwa BB, Wang Q, Cao B, Xu S (2016) Co-pyrolysis mechanism of
890
seaweed polysaccharides and cellulose based on macroscopic experiments and molecular simulations. Bioresource
891
Technol 228: 305-314.
892
[95] Yang W, Xu W, Liu Z, Liu YX (2018) Removal of elemental mercury from flue gas using sargassum chars
893
modified by NH4Br reagent. Fuel 214: 196-206.
894
[96] Yang W, Shan Y, Ding S, Han X, Liu YX, Pan J (2019) Gas-phase elemental mercury removal using
895
ammonium chloride impregnated sargassum chars. Environ Technol 40: 1923-1936.
896
[97] Xu W, Pan J, Fan B, Liu YX (2019) Removal of gaseous elemental mercury using seaweed chars
897
impregnated by NH4Cl and NH4Br. J Clean Prod 216: 277-287.
898
[98] Liu Z, Yang W, Xu W, Liu YX (2018) Removal of elemental mercury by bio-chars derived from seaweed
899
impregnated with potassium iodine. Chem Eng J 339: 468-478.
900
[99] Liu Z, Adewuyi YG, Shi S, Chen H, Li Y, Liu DJ, Liu YX (2019) Removal of gaseous Hg0 using novel
44
901
seaweed biomass-based activated carbon. Chem Eng J 366: 41-49.
902
[100] Wang QH, Bellisario DO, Drahushuk LW, Jain RM, Kruss S, Landry MP, Mahajan SG, Shimizu SFE,
903
Ulissi ZW, Strano MS (2014) Low dimensional carbon materials for applications in mass and energy transport.
904
Chem Mater 26: 172-183.
905
[101] Liu DJ, Zhou W, Wu J, Huang T (2018) Fractal characterization of graphene oxide nanosheet. Mater Lett
906
220: 40-43.
907
[102] Novoselov KS, Geim AK, Morozov SV, Jiang D, Zhang Y, Dubonos SV, Grigorieva IV, Firsov AA (2004)
908
Electric field effect in atomically thin carbon films. Science 306: 666-669.
909
[103] Zhou C, Zhu H, Wang Q, Wang J, Cheng J, Guo Y, Zhou, X, Bai R (2017) Adsorption of mercury(ii) with
910
an Fe3O4 magnetic polypyrrole-graphene oxide nanocomposite. RSC Adv 7: 18466-18479.
911
[104] Zhao Y, Nie G, Ma X, Xu P, Zhao X (2019) Peroxymonosulfate catalyzed by rGO assisted CoFe2O4
912
catalyst for removing Hg0 from flue gas in heterogeneous system. Environ Pollut 249: 868-877.
913
[105] Xu, H, Qu Z, Zong C, Huang W, Quan, F, Yan N (2015) MnOx/graphene for the catalytic oxidation and
914
adsorption of elemental mercury. Environ Sci Technol 49: 6823-6830.
915
[106] Xu H, Qu Z, Huang W, Mei J, Chen W, Zhao S, Yan N (2015) Regenerable Ag/graphene sorbent for
916
elemental mercury capture at ambient temperature. Colloid Surface A 476: 83-89.
917
[107] Ma Y, Mu B, Zhang X, Yuan D, Ma C, Xu H, Qu Z, Fang S (2019) Graphene enhanced Mn-Ce binary
918
metal oxides for catalytic oxidation and adsorption of elemental mercury from coal-fired flue gas. Chem Eng J
919
358: 1499-1506.
920
[108] Liu Y, Tian C, Yan B, Lu Q, Xie Y, Chen J, Gupta R, Xu Z, Kuznicki SM, Liu Q, Zeng H (2015)
921
Nanocomposites of graphene oxide, Ag nanoparticles, and magnetic ferrite nanoparticles for elemental mercury
922
(Hg0) removal. RSC Adv 5: 15634-15640.
45
923
[109] An D, Zhang X, Dong Y (2018) Performance of Mn-Fe-Ce/GO-x for catalytic oxidation of Hg0 and
924
selective catalytic reduction of NOx in the same temperature range. Catalysts 8: 399.
925
[110] Ma Y, Mu B, Zhang X, Qu Z, Gao L, Li B, Tian J (2019) Ag-Fe3O4@rGO ternary magnetic adsorbent for
926
gaseous elemental mercury removal from coal-fired flue gas. Fuel 239: 579-586.
927
[111] Meeprasert J, Junkaew A, Rungnim C, Kunaseth M, Kungwan N, Promarak V, Namuangruk S (2016)
928
Capability of defective graphene-supported Pd13 and Ag13 particles for mercury adsorption. Appl Surf Sci 364:
929
166-175.
930
[112] Jungsuttiwong S, Wongnongwa Y, Namuangruk S, Kungwan N, Promarak V, Kunaseth M (2016) Density
931
functional theory study of elemental mercury adsorption on boron doped graphene surface decorated by transition
932
metals. Appl Surf Sci 362: 140-145.
933
[113] Zhao C, Wu H (2017). Density functional investigation of mercury and arsenic adsorption on nitrogen
934
doped graphene decorated with palladium clusters: a promising heavy metal sensing material in farmland. Appl
935
Surf Sci 399: 55-66.
936
[114] Liu Z, Zhang Y, Wang B, Chen H, Cheng X, Huang Z (2018) DFT study on Al-doped defective graphene
937
towards adsorption of elemental mercury. Appl Surf Sci 427: 547-553.
938
[115] Tasis D, Tagmatarchis N, Bianco A, Prato M (2006) Chemistry of carbon nanotubes. Chem Rev 106:
939
1105-1113.
940
[116] Huang B, Yue J, Wei Y, Huang X, Tang X, Du Z (2019) Enhanced microwave absorption properties of
941
carbon nanofibers functionalized by FeCo coatings. Appl Surf Sci 483: 98-105.
942
[117] Zhao B, Liu X, Zhou Z, Shao H, Xu M (2016) Catalytic oxidation of elemental mercury by Mn-Mo/CNT at
943
low temperature. Chem Eng J 284: 1233-1241.
944
[118] Ma Y, Zhang D, Wu J, Liang P, Zhang H (2018) Fe-Ce mixed oxides supported on carbon nanotubes for
46
945
simultaneous removal of NO and Hg0 in flue gas. Ind Eng Chem Res 57: 3187-3194.
946
[119] Yao Y, Velpari V, Economy J (2014) Design of sulfur treated activated carbon fibers for gas phase
947
elemental mercury removal. Fuel 116: 560-565.
948
[120] Yang J, Zhao Y, Liang S, Zhang S, Ma S, Li H, Zhang J, Zheng C (2018) Magnetic iron-manganese binary
949
oxide supported on carbon nanofiber (Fe3-xMnxO4/CNF) for efficient removal of Hg0 from coal combustion flue
950
gas. Chem Eng J 334: 216-224.
951
[121] Xia Y, Liao Z, Zheng Y, Zhou Z (2018) Highly dispersed Mn-Ce binary metal oxides supported on carbon
952
nanofibers for Hg0 removal from coal-fired flue gas. Appl Sci 8: 2501.
953
[122] Romero-Anaya AJ, Lillo-Ródenas MA, Linares-Solano A (2014) Activation of a spherical carbon for
954
toluene adsorption at low concentration. Carbon 77: 616-626.
955
[123] Ludwinowicz J, Jaroniec M (2015) Potassium salt-assisted synthesis of highly microporous carbon spheres
956
for CO2 adsorption. Carbon 82: 297-303.
957
[124] Xu H, Jia J, Guo Y, Qu Z, Liao Y, Xie J, Shangguan W, Yan N (2018) Design of 3D MnO2-Carbon sphere
958
composite for the catalytic oxidation and adsorption of elemental mercury. J Hazard Mater 342: 69-76.
959
[125] Zhang C, Song W, Zhang X, Li R, Zhao S, Fan C (2018) Synthesis characterization and evaluation of
960
resin-based carbon spheres modified by oxygen functional groups for gaseous elemental mercury capture. J Mater
961
Sci 53: 9429-9448.
962
[126] Zhang C, Song W, Zhang X, Li R, Zhao S, Fan C (2019) Synthesis and evaluation of activated carbon
963
spheres with copper modification for gaseous elemental mercury removal. J Porous Mater 26: 693-703.
964
[127] Zhang C, Song W, Zhang X, Li R, Zhao S, Fan C (2019)
965
spheres by grafting and coordinating reactions for elemental mercury removal. J Mater Sci 54: 2836-2852.
966
[128] Chen T, Guo S, Yang J, Xu Y, Sun J, Wei D, Chen Z, Zhao B, Ding W (2017) In situ activated
47
Synthesis of CeO2-modified activated carbon
967
nitrogen-doped carbon by embeded nickel via Mott-Schottky effect for oxygen reduction reaction.
968
ChemPhysChem 18: 3454-3461.
969
[129] Rowsell JLC, Yaghi OM (2004) Metal-organic frameworks: a new class of porous materials. Micropor
970
Mesopor Mat 73: 3-14.
971
[130] Jiang H, Wang C, Wang H, Zhang M (2016) Synthesis of highly efficient MnOx catalyst for
972
low-temperature NH3-SCR prepared from Mn-MOF-74 template. Mater Lett 168: 17-19.
973
[131] Li Y, Wang L, Fan H, Shangguan J, Wang H, Mi J (2015) Removal of sulfur compounds by a copper-based
974
metal organic framework under ambient conditions. Energy Fuels 29: 298-304.
975
[132] Sun X, Shi Y, Zhang W, Li C, Zhao Q, Gao J, Li X (2018) A new type Ni-MOF catalyst with high stability
976
for selective catalytic reduction of NOx with NH3. Catal Commun 114: 104-108.
977
[133] Yaghi OM, Li H (1995) Hydrothermal synthesis of a metal-organic framework containing large rectangular
978
channel. J Am Chem Soc 117: 10401-10402.
979
[134] Li H, Eddaoudi M, O’Keeffe M, Yaghi OM (1999) Design and synthesis of an exceptionally stable and
980
highly porous metal-organic framework. Nature 402: 276-279.
981
[135] Kaye SS, Dailly A, Yaghi OM, Long JR (2007) Impact of preparation and handling on the hydrogen storage
982
properties of Zn4O(1, 4-benzenedicarboxylate)3(MOF-5). J Am Chem Soc 129: 14176-14177.
983
[136] Rosi NL, Eckert J, Eddaoudi M, Vodak DT, Kim J, O’Keeffe M, Yaghi OM (2003) Hydrogen storage in
984
microporous metal-organic frameworks. Science 300: 1127-1129.
985
[137] Bao Z, Alnemrat S, Yu L, Vasiliev I, Ren Q, Lu X, Deng S (2011) Adsorption of ethane, ethylene, propane,
986
and propylene on a magnesium-based metal-organic framework. Langmuir 27: 13554-13562.
987
[138] Wu X, Bao Z, Yuan B, Wang J, Sun Y, Luo H, Deng S (2013) Microwave synthesis and characterization of
988
MOF-74 (M=Ni, Mg) for gas separation. Micropor Mesopor Mat 180: 114-122.
48
989
[139] Lee JY, Farha OK, Roberts J, Scheidt KA, Nguyen SBT, Hupp JT (2009) Metal-organic framework
990
materials as catalysts. Chem Soc Rev 38: 1450-1459.
991
[140] Tan HY, Zhou Y, Yan YF, Wu DY, Hu WB, Shi XY (2017) Metal organic framework
992
Cu/MIL-53(Ce)-mediated synthesis of highly active and stable CO oxidation catalysts. Inorg Chem Commun 79:
993
74-77.
994
[141] Sun H, Zhang H, Mao H, Yu B, Han J, Bhat G (2019) Facile synthesis of the magnetic metal–organic
995
framework Fe3O4/Cu3(BTC)2 for efficient dye removal. Environ Chem Lett 17: 1091-1096.
996
[142] Kumar A, Rana A, Sharma G, Sharma S, Naushad M, Mola GT, Dhiman P, Stadler FJ (2018) Aerogels and
997
metal–organic frameworks for environmental remediation and energy production. Environ Chem Lett 16:
998
797-820.
999
[143] Liu Y, Li H, Liu J (2016) Theoretical prediction the removal of mercury from flue gas by MOFs. Fuel 184:
1000
474-480.
1001
[144] Zhang X, Shen B, Zhu S, Xu H, Tian L (2016) UiO-66 and its Br-modified derivates for elemental mercury
1002
removal. J Hazard Mater 320: 556-563.
1003
[145] Zhang X, Shen B, Shen F, Zhang X, Si M, Yuan P (2017) The behavior of the manganese-cerium loaded
1004
metal-organic framework in elemental mercury and NO removal from flue gas. Chem Eng J 326: 551-560.
1005
[146] Zhao S, Chen D, Xu H, Mei J, Qu Z, Liu P, Cui Y, Yan N (2018) Combined effects of Ag and UiO-66 for
1006
removal of elemental mercury from flue gas. Chemosphere 197: 65-72.
1007
[147] Chen D, Zhao S, Qu Z, Yan N (2018) Cu-BTC as a novel material for elemental mercury removal from
1008
sintering gas. Fuel 217: 297-305.
1009
[148] Zhao S, Mei J, Xu H, Liu W, Qu Z, Cui Y, Yan N (2018) Research of mercury removal from sintering flue
1010
gas of iron and steel by the open metal site of Mil-101(Cr). J Hazard Mater 351: 301-307.
49
1011
[149] Zhou J, Cao L, Wang Q, Tariq M, Xue Y, Zhou Z, Sun W, Yang J (2019) Enhanced Hg0 removal via
1012
α-MnO2 anchored to MIL-96(Al). Appl Surf Sci 483: 252-259.
1013
[150] Yang J, Zhu W, Qu W, Yang Z, Wang J, Zhang M, Li H (2019) Selenium functionalized metal-organic
1014
framework MIL-101 for efficient and permanent sequestration of mercury. Environ Sci Technol 53: 2260-2268.
1015
[151] Wang X, Blechert S, Antonietti M (2012) Polymeric graphitic carbon nitride for heterogeneous
1016
photocatalysis. ACS Catal 2: 1596-1606.
1017
[152] Kumar A, Thakur PR, Sharma G, Naushad M, Rana A, Mola GT, Stadler FJ (2019) Carbon nitride, metal
1018
nitrides, phosphides, chalcogenides, perovskites and carbides nanophotocatalysts for environmental applications.
1019
Environ Chem Lett 17: 655-682.
1020
[153] Liang Q, Li Z, Bai Y, Huang Z, Kang F, Yang Q (2017) Reduced-sized monolayer carbon nitride
1021
nanosheets for highly improved photoresponse for cell imaging and photocatalysis. Sci China Mater 60: 109-118.
1022
[154] Wang Y, Wang X, Antonietti M (2012) Polymeric graphitic carbon nitride as a heterogeneous
1023
organocatalyst: from photochemistry to multipurpose catalysis to sustainable chemistry. Angew Chem Int Ed 51:
1024
68-89.
1025
[155] Wang X, Maeda K, Thomas A, Takanabe K, Xin G, Carlsson JM, Domen K, Antonietti MA (2009)
1026
Metal-free polymeric photocatalyst for hydrogen production from water under visible light. Nat Mater 8: 76-82.
1027
[156] Xiao J, Xie Y, Cao H, Wang Y, Guo Z, Chen Y (2016) Towards effective design of active nanocarbon
1028
materials for integrating visible-light photocatalysis with ozonation. Carbon 107: 658-666.
1029
[157] Dong G, Yang L, Wang F, Zang L, Wang C (2016) Removal of nitric oxide through visible light
1030
photocatalysis by g-C3N4 modified with perylene imides. ACS Catal 6: 6511-6519.
1031
[158] Tang J, Guo R, Pan W, Zhou W, Huang C (2019) Visible light activated photocatalytic behaviour of Eu (III)
1032
modified g-C3N4 for CO2 reduction and H2 evolution. Appl Surf Sci 467-468: 206-212.
50
1033
[159] Lu C, Wu J, Liu DJ (2018) Graphitic carbon nitride for elemental mercury capture. Mater Lett 227:
1034
308-310.
1035
[160] Liu DJ, Lu C, Wu J (2018) CuO/g-C3N4 nanocomposite for elemental mercury capture at low temperature. J
1036
Nanopart Res 20: 277.
1037
[161] Liu DJ, Lu C, Wu J (2018) Gaseous mercury capture by copper-activated nanoporous carbon nitride.
1038
Energy Fuels 32: 8287-8295.
1039
[162] Niu P, Zhang L, Liu G, Cheng H (2012) Graphene-like carbon nitride nanosheets for improved
1040
photocatalytic activities. Adv Funct Mater 22: 4763-4770.
1041
[163] Xu J, Zhang L, Shi R, Zhu Y (2013) Chemical exfoliation of graphitic carbon nitride for efficient
1042
heterogeneous photocatalysis. J Mater Chem A 1: 14766-14772.
1043
[164] Liu DJ, Zhang Z, Wu J (2019) Elemental mercury removal by MnO2 nanoparticle decorated carbon nitride
1044
nanosheet. Energy Fuels 33: 3089-3097.
1045
[165] Zhang Z, Wu J, Liu DJ (2019) Co3O4/g-C3N4 hybrids for gas-phase Hg0 removal at low temperature.
1046
Processes 7: 279.
1047
[166] Liu DJ, Lu C, Wu J (2018) Elemental mercury adsorption by cupric chloride-modified mesoporous carbon
1048
aerogel. Colloids Interfaces 2: 66.
1049
[167] Zhang H, Zhang D, Wang J, Xu W, Yang D, Jiao T, Zhang W, Liang P (2019) Simultaneous removal of
1050
Hg0 and H2S at a high space velocity by water resistant SnO2/carbon aerogel. J Hazard Mater 371: 123-129.
1051
[168] Ma Y, Qi P, Ju J, Wang Q, Hao L, Wang R, Sui K, Tan Y (2019) Gelatin/alginate composite nanofiber
1052
membranes for effective and even adsorption of cationic dyes. Compos Part B-Eng 162: 671-677.
1053
[169] Liu DJ, Wang Q, Wu J, Liu YX (2019) A review of sorbents for high-temperature hydrogen sulfide removal
1054
from hot coal gas. Environ Chem Lett 17: 259-276.
51
1055
[170] Wu Z, Liang H, Hu B, Yu S (2018) Emerging carbon-nanofiber aerogels: chemosynthesis versus
1056
biosynthesis. Angew Chem Int Ed 57: 15646-15662.
1057
[171] Wang Y, Han X, Liu YX. (2019) Removal of Carbon Monoxide from Simulated Flue Gas Using Two New
1058
Fenton Systems: Mechanism and Kinetics. Environ Sci Technol 51:11950–11959.
1059
[172] Shen FH, Liu J, Dong YC. (2019) Elemental mercury removal from syngas by porous carbon-supported
1060
CuCl2 sorbents. Fuel 239: 138-144.
1061
[173] Wang Y, Liu YX, Liu Y. (2019) Elimination of nitric oxide using new Fenton process based on synergistic
1062
catalysis: Optimization and mechanism. Chem Eng J 372: 92-98.
1063
[174] Shen FH, Liu J. (2019) Design of O2/SO2 dual-doped porous carbon as superior sorbent for elemental
1064
mercury removal from flue gas. J Hazard Mater 366: 321-328.
1065
[175] Liu YX, Wang Y, Liu ZY, Wang Q. (2017) Oxidation Removal of Nitric Oxide from Flue Gas Using UV
1066
Photolysis of Aqueous Hypochlorite. Environ Sci Technol 51:11950-11959.
1067
[176] Wang Y, Wang ZL, Pan JF, Liu YX. (2019) Removal of Hydrogen Sulfide Using Fenton Reagent in A
1068
Spraying Reactor. Fuel 239: 70-75.
1069
[177] Shen FH, Liu J. (2019) Development of O2 and NO co-doped porous carbon as high-capacity mercury
1070
sorbent. Environ Sci Technol 53: 1725-1731.
1071
[178] Wang Y, Liu YX, Xu JJ. (2019) Separation of Hydrogen Sulfide from Gas Phase Using Ce3+/Mn2+-
1072
Enhanced Fenton-Like Oxidation System. Chem Eng J 359:1486-1492.
1073
[179] Liu DJ, Li B, Wu J. (2019)Sorbents for hydrogen sulfide capture from biogas at low temperature: a review.
1074
Environ Chem Lett . https://doi.org/10.1007/s10311-019-00925-6
1075
[180] Lu CY, Wei MY. (2007) Simultaneous removal of VOC and NO by activated carbon impregnated with
1076
transition metal catalysts in combustion flue gas. Fuel Process Technol 359:1486-1492
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Graphical Abstract
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1. The prospect and limitation of low-dimensional carbon for Hg0 removal are commented.
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2. Bio-char, carbon nitride, and metal-organic framework are promising mercury sorbents.
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3. The performances and mechanisms of diverse carbon-based sorbents are fully discussed.
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Declaration of Interest Statement
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(1) All authors declare that we have no financial and personal relationships with other people,
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organizations or company that can inappropriately influence our work. The authors also state
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that the processing of this manuscript will not receive any organizational or personal
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interference.
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(2) All authors declare that the copyright of this manuscript is entirely determined by the
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submitting publisher and/or the journal. The authors have no interest disputes about this
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publishing rights or future commercial interests.
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(3) All authors agree to the corresponding author's submission decision and ensure that there are no disputes of interest.
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