Effects of particle size, pretreatment, and catalysis on microwave pyrolysis of corn stover

Accepted Manuscript Effects of particle size, pretreatment, and catalysis on microwave pyrolysis of corn stover Yu-Fong Huang, Wen-Hui Kuan, Chun-Yuan Chang PII:

S0360-5442(17)31872-8

DOI:

10.1016/j.energy.2017.11.022

Reference:

EGY 11810

To appear in:

Energy

Received Date: 18 April 2017 Revised Date:

26 October 2017

Accepted Date: 5 November 2017

Please cite this article as: Huang Y-F, Kuan W-H, Chang C-Y, Effects of particle size, pretreatment, and catalysis on microwave pyrolysis of corn stover, Energy (2017), doi: 10.1016/j.energy.2017.11.022. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Effects of particle size, pretreatment, and catalysis on microwave

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pyrolysis of corn stover

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Yu-Fong Huang a, Wen-Hui Kuan b,*, Chun-Yuan Chang b

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Chou-Shan Rd., Taipei 106, Taiwan, ROC b

Department of Safety, Health and Environmental Engineering, Ming Chi University of Technology, 84 Gong-Juan Rd., Taishan, New Taipei City 243, Taiwan, ROC

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Graduate Institute of Environmental Engineering, National Taiwan University, 71

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Corresponding author. Tel.: +886 2 2908 9899 ext 4653; fax: +886 2 2908 0346. Email address: [email protected] (W.-H. Kuan).

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Abstract

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The effects of particle size, pretreatment (acid pretreatment and steam explosion), and catalysis of aluminum oxide (Al2O3) on heating efficiency, product distribution, and

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gaseous product composition of corn stover pyrolysis using microwave heating were

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investigated in this study. Both maximum temperature and heating rate increased with

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decreasing particle size of corn stover. The heating efficiency was also improved over

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Al2O3 and by applying both pretreatment methods. Adding 10-mesh Al2O3 increased the

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gaseous yield but decreased the liquid yield. However, this phenomenon did not exist

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when 50-mesh Al2O3 was used. This may be attributable to that small catalyst particles

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are encapsulated by other catalyst and biomass particles to reduce their catalytic activity.

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Applying acid pretreatment substantially decreased the gaseous yield but increased the

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liquid yield, whereas the effect of steam explosion was not significant. Approximately

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half of CO was produced during the first 5 min of experiment, but the yields of H2, CH4,

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and CO2 produced from microwave pyrolysis of corn stover pretreated by acid were

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relatively small or even none during this initial period. The reaction kinetics for

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microwave pyrolysis of corn stover was analyzed by using the first- and second-order

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reaction models.

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Keywords: Microwave pyrolysis; Corn stover; Particle size; Pretreatment; Catalysis; Reaction kinetics

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1. Introduction

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Renewable energy systems, such as solar photovoltaics, wind power, and biofuels, have attracted increasing interest mainly because of concerns about growing demand for

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limited, non-renewable fossil fuels and issues related to climate change (i.e., global

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warming, extreme events and disasters, sea ice melting, sea level rising, ocean

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acidification, etc.) caused by emissions of anthropogenic greenhouse gases [1–7]. The

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world’s total energy consumption has been almost doubled from 4,667 Mtoe (million

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tonnes of oil equivalent) in 1973 to 9,301 Mtoe in 2013 [8]. The Paris Agreement in the

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21st Conference of the Parties (COP 21) to the United Nations Framework Convention

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on Climate Change (UNFCCC) has reset the collective global climate ambition from the

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aspiration of keeping temperature rise below 2 °C (relative to pre-industrial levels), to a

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new aim of limiting it to well below 2 °C with efforts to pursue 1.5 °C, so attention

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must turn to further reducing emissions remaining within energy scenarios consistent

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with 2 °C warming [9]. The Paris Agreement is the first climate deal with universal

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contributions to mitigation action, and its strengthened long-term objectives require

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even stronger actions than previously identified [10]. Therefore, the research and

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development of renewable energy is so important and urgent, to reduce the dependence

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on fossil fuels and thus to mitigate the climate change.

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Biomass energy (bioenergy) is one of the forms of renewable energy. Biomass has

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been recognized as an abundant carbon-neutral renewable resource for the production of

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value-added bioenergy and biomaterials [1–3]. In contrast to other renewables

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supplying heat and power, biomass is the only currently source of solid, liquid, and

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ACCEPTED MANUSCRIPT gaseous fuels [11]. Besides, negative carbon dioxide emissions can be accomplished by

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using biochar (solid carbonaceous residues from biomass pyrolysis) for carbon

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sequestration [12] or by bio-energy with carbon capture and storage (BECCS) [13].

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Lignocellulosic biomass is mainly composed of structural constituents (hemicelluloses,

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cellulose, and lignin), and it can be converted into bioenergy by using thermochemical

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and biological processes [14]. Pyrolysis, which is the direct thermal decomposition of

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biomass in the absence of oxygen to obtain solid, liquid, and gaseous products, has been

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widely recognized as the preferred conversion method of various thermochemical

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processes available [11,14–16].

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Biomass pyrolysis is conventionally carried out by means of electric heating furnaces. However, microwave heating can offer a number of advantages over

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conventional heating such as: (i) higher heating rates and efficiencies, (ii) non-contact

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heating, (iii) material-selective heating, (iv) volumetric and uniform heating, (v) energy

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transfer rather than heat transfer, (vi) energy savings at significantly reduced processing

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temperatures (150–300 °C), (vii) less feedstock pretreatment needed, (viii) quick

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start-up and stopping, (ix) greater control and safety, and (x) reduced equipment size

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and waste [17–22]. Therefore, microwave heating has been applied in various fields.

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Biomass pyrolysis heated by microwave irradiation has been proven as an efficient

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technique for the production of fuels and materials [20,22–26]. More work is still

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needed to extend existing understanding of microwave pyrolysis characteristics in order

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to improve the technique and then to transform it into a commercially viable route for

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the production of fuels and materials in an environmentally sustainable manner [24].

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Corn stover, the crop residue left in cornfields, is produced at a ratio of approximately 1 kg per kg of corn grain (on dry basis) [27]. Corn stover is abundant

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since more than 216 Tg can be produced annually in the United States [28]. The annual

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corn stover production was approximately 114 Gg in Taiwan, based on the corn grain

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production data in 2014 [29]. Corn is one of the most important crops in the world, so

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its residues can be regarded as a sustainable bioenergy resource [27,30]. This study was

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aimed at investigating the effects of particle size, catalysis, and pretreatment on the

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gaseous products produced from corn stover by using microwave pyrolysis. A number

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of studies have focused on the effect of either particle size or catalysis on microwave

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pyrolysis of biomass, but there is seldom work about the effect of pretreatment on

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product distribution as well as the explanation of the effect. Besides, the reaction

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kinetics for microwave pyrolysis of corn stover under different conditions was analyzed.

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2. Material and methods

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2.1 Materials

Raw corn stover feedstock was collected in the cornfields and markets of Taiwan.

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Prior to pretreatment and microwave pyrolysis, the corn stover was naturally dried by

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exposure to air in an open area for 14 days, and then it was mechanically shredded and

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manually sieved. By using different sieves, five corn stover samples with different

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particle sizes were obtained: >4.00, 2.00–4.00, 0.425–2.00, 0.250–0.425, and

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0.150–0.250 mm, simply named as 5, 10, 40, 60, and 100 mesh, respectively, in this

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study. The catalyst used in this study was Al2O3 purchased from Kokusan Chemical

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Works (Japan), and it was sieved by 10 and 50 mesh screens.

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2.2 Pretreatment

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109 Two pretreatment methods were applied in this study: acid pretreatment and steam explosion. In the acid pretreatment, each 1 g dry corn stover was merged with proper

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stirring into an aqueous solution containing 1 mL deionized water and 10 mL

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phosphoric acid (85 %). Sufficient materials for all experiments were pretreated in

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advance. Phosphoric acid was used in this study because it is one of the common acids

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for the acid pretreatment of lignocellulosic biomass [31,32]. The solution was heated in

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a 323 K water bath for 10 h, and then it was mixed with 50 mL deionized water with

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strong stirring. Afterwards the corn stover was washed with plenty of deionized water.

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The pH value of corn stover was adjusted to neutral by using a NaOH solution. In the

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steam explosion, the dry corn stover was put into an autoclave under the condition of

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160–260 °C and 6–34 bar. The environmental condition was held for 1 min when it was

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reached. The pretreated corn stover was naturally dried by exposure to air in an open

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area for 14 days and shredded to the designated particle size.

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2.3 Experimental apparatus

Microwave pyrolysis of corn stover was carried by using a single-mode microwave

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oven operating at a frequency of 2.45 GHz. The microwave oven was purchased from

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MUEGGE (Germany). The layout of the overall microwave pyrolysis system can be

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found elsewhere [33]. Both reaction tube (40 cm in length and 5 cm in outer diameter)

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ACCEPTED MANUSCRIPT and crucible (3 cm in height and 4 cm in outer diameter) were made of quartz material.

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A K-type thermocouple sensor was placed outside the bottom of the quartz crucible to

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measure the real-time temperature of corn stover sample. Pure nitrogen gas (99.99%)

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was purged into the system at a flow rate of 50 mL/min to ensure the anoxic condition

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in the reaction system. The actual working microwave power level was determined by

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the incident power level subtracting the reflected power level.

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The corn stover sample or its blend with Al2O3 was added to the quartz crucible and then placed inside the quartz reaction tube. Each pretreated or non-pretreated corn

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stover was weighed to 2 g. In catalytic pyrolysis experiments, 2 g corn stover was

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blended with the catalyst by 5 wt% (i.e., totally 2.1 g). The height of the quartz crucible

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was adjusted to be located in the path of microwave propagation. After sufficient

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nitrogen gas purging, the power supply was turned on and the adjustment knob was

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switched to a microwave power level of 500 W. The power level was selected because

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of insufficient and over heating for biomass pyrolysis at lower and higher power levels,

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respectively. After microwave irradiation for 20 min, the power supply was turned off,

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and the carrier gas purging was stopped. The vapor produced during the experiment

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immediately passed through a condenser tube whose temperature was controlled at 4 °C

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by a thermostat. The condensable and non-condensable parts of the product vapor were

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regarded as liquid and gaseous products, respectively. The gaseous product was

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collected every 5 min in a 5 L Tedlar bag. After self-cooled down to room temperature,

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the solid residues remained in the quartz crucible were removed, weighed, and then

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stored in a desiccator. All of the experiments were performed at least in triplicate to

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obtain average values for the experimental results.

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The proximate analysis of corn stover was carried out according to the standard

test method E1131–08 of the American Society for Testing and Materials (ASTM). The

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moisture content of corn stover was 4.97 wt%. The volatile matter, fixed carbon, and

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ash contents (on dry basis) of corn stover were 90.59, 6.94, and 2.47 wt%, respectively.

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The higher heating value (HHV) of corn stover was measured in a CAL2K ECO

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adiabatic oxygen bomb calorimeter. Each sample (approximately 0.5 g) was dried at 105

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°C prior to the heating value analysis. The average HHV of corn stover was 18.41

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MJ/kg. Gaseous product analysis was carried out by using the Perkin–Elmer Auto

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System XL gas chromatography–thermal conductivity detector (GC–TCD) equipped

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with a Supelco Carboxen 1010 PLOT column. The temperatures of injector, oven, and

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detector were controlled at 120, 100, and 150 °C, respectively. The flow rate of carrier

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gas (He or N2) was set at 10 mL/min (25:1 split).

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3. Results and discussion

3.1 Temperature profiles

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The temperature profiles of microwave pyrolysis of corn stover are illustrated in Fig. 1. As can be seen in, both maximum temperature and heating rate generally

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ACCEPTED MANUSCRIPT increased with decreasing particle size. The maximum temperatures of 5, 10, 40, 60, and

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100 mesh corn stover were 475, 478, 557, 522, and 557 °C, and the average heating

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rates during the first 5 min were 84.6, 75.4, 95.2, 86.4, and 94.6 °C/min, respectively.

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The reaction temperature was continuously recorded to obtain the real-time temperature

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change and the arithmetic average heating rate. The average heating rate during the first

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5 min was considered because the heating ramp in this period was much more

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significant than afterwards, no matter which particle size it was. The effects of

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pretreatment and catalysis on the temperature profiles of microwave pyrolysis of corn

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stover can be observed by Fig. 1b. It can be seen that, without any pretreatment, the

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effect of adding 10-mesh Al2O3 was insignificant. However, after either acid

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pretreatment or steam explosion, the catalytic effect turned to be substantial.

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Furthermore, after acid pretreatment, the maximum temperature of catalytic microwave

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pyrolysis of corn stover was highest.

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To further observe the effects of pretreatment and catalysis, the maximum temperatures and average heating rates during the first 5 min of microwave pyrolysis of

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corn stover under various conditions are shown in Fig. 2. In general, both maximum

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temperature and heating rate increased with decreasing particle size of corn stover, no

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matter the catalyst was added or not. When the particle size was reduced from 5 mesh to

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100 mesh, the maximum temperature and heating rate increased by 67–82 °C and 10–18

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°C/min, respectively. Besides, the addition of catalyst promoted both maximum

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temperature and heating rate in some cases. After acid pretreatment and steam explosion,

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(approximately 106 °C/min), and the heating rates of catalytic microwave pyrolysis

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were also close to each other (approximately 110 °C/min). On the other hand, the

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maximum temperatures of microwave pyrolysis of corn stover were not so different

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(604–610 °C). However, the maximum temperature of catalytic microwave pyrolysis of

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acid pretreated corn stover was 654 °C, much higher than that (628 °C) when steam

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explosion was applied. According to the aforementioned experimental results, it is clear

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that all the three factors (particle size, pretreatment, and catalysis) had substantial

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effects to increase the efficiency of microwave heating. In addition, the effect of

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pretreatment seems to be stronger than that of catalysis. Microwave heating can be

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referred to as dielectric heating [17,19]. The different maximum temperatures and

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heating rates could be attributable to the difference in dielectric property of corn stover

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with and without catalyst or pretreatment, since the composition of the biomass would

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be changed after the processes.

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Figure 2

3.2 Product distribution

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After microwave pyrolysis, corn stover was converted into solid, liquid, and

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gaseous products. The three-phase product distributions under various operational

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conditions are shown in Fig. 3. It should be noted that the quantities of solid and

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gaseous products were directly measured, and the solid amount is without the catalyst.

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However, the percentage of liquid product was taken as the difference between 100 and

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ACCEPTED MANUSCRIPT the sum of the other phases, because it was difficult to completely collect the liquid

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product. In general, gaseous yield increased but both solid and liquid yields decreased

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with decreasing particle size. The addition of 10-mesh Al2O3 increased the gaseous

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yield by approximately 4–9 wt%, but adding 50-mesh Al2O3 decreased the yield by

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approximately 3–7 wt%. The results indicate that the relatively small particle size of

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catalyst may hinder the further (secondary) degradation of the organic vapor released by

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corn stover pyrolysis. Consequently, the three-phase product distributions of microwave

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pyrolysis of corn stover with and without 50-mesh Al2O3 were similar to each other. The

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gaseous yields of microwave pyrolysis of 10–100 mesh corn stover samples were up to

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70–72 wt%, when the 10-mesh Al2O3 was added. The gaseous yield of 60-mesh corn

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stover without adding catalyst was 73 wt%. This could be attributable to the impurity of

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biomass sample or the unknown characteristics of microwave heating. It is a

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coincidence that the product yields of 40-mesh in Fig. 3c are very close to those of

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SE-NC in Fig. 3d. This may imply that the addition of 50-mesh Al2O3 and the

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pretreatment of steam explosion provide similar effect on product distribution. It has

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been reported that the gaseous yield of catalytic microwave pyrolysis was

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approximately 40–60 wt% [34–36], lower than the data in this study. This could be

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attributable to the catalytic effect accomplished by Al2O3 and the heating efficiency

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provided by single-mode microwave oven.

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Figure 3

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The catalytic effect and the difference in the product distributions of biomass pyrolysis over 10- and 50-mesh Al2O3 can be explained by Fig. 4. The product vapor

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ACCEPTED MANUSCRIPT released by biomass pyrolysis leaves the reaction system within a short time (depending

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on the flow rate of carrier gas and the configuration of reactor and pipelines), when

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there is no catalyst added. By using a condenser, the product vapor is divided into

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condensable and non-condensable parts, namely liquid and gaseous products,

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respectively. When a catalyst is added to the biomass, part of the product vapor can be

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entrapped by the catalyst particles and then decomposes into smaller substances such as

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light hydrocarbons (CH4, C2H4, C2H6, etc.) and permanent gases (H2, CO, and CO2)

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[37–39]. Consequently, catalytic pyrolysis produces more gaseous product than

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conventional pyrolysis. However, if the catalyst particles are too small, they may be

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encapsulated by other catalyst and biomass particles to reduce their catalytic activity. As

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a result, the gaseous yield of biomass pyrolysis over small catalyst particles would be

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lower than expected.

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Figure 4

After acid pretreatment, the liquid yield of microwave pyrolysis of corn stover

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substantially increased by approximately 15 wt% whereas the gaseous yield decreased

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by approximately 14 wt%. The result could be attributable to the depolymerization and

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hydrolysis of hemicellulose and cellulose during the acid pretreatment [40–45], so there

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was less formation of primary products that can be further converted into permanent

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gases. On the other hand, the effect of steam explosion pretreatment was not significant.

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The product distribution of microwave pyrolysis of corn stover pretreated by steam

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explosion was not so different from that without any pretreatment. Therefore, the extent

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of hemicellulose and cellulose solubilization accomplished by steam explosion could be

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microwave pyrolysis of pretreated corn stover was higher than that without adding

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catalyst by approximately 3 wt%, no matter which pretreatment method was used. The

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solid yields, which were nearly the same under different operational conditions, could

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be regarded as an allowable minimum value for the microwave pyrolysis of corn stover

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at a microwave power level of 500 W.

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The quantities of H2, CH4, CO2, and CO produced by microwave pyrolysis of 40-mesh corn stover with and without pretreatment and catalysis are shown in Fig. 5.

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For the total processing time of 20 min, the overall production quantities of H2, CH4,

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CO2, and CO under different conditions were in the ranges of 0.001–0.05, 0.02–0.04,

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0.01–0.05, and 0.91–1.15 L, respectively. It can be seen that of quantity of CO was

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mush bigger than those of other gases. The composition of gaseous product was

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different from those reported in the literature [35,36]. This could be attributable to the

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difference in product selectivity among the catalysts (char-supported metallic catalysts

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[35], HZSM-5 aluminosilicate zeolite [36], and Al2O3 in this study). Approximately half

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of CO was produced during the first 5 min, and then it was stably produced until the end

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of the process. H2, CH4, and CO2 were not regularly generated as CO was. Most of them

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were produced during 5–20 min. In general, adding catalyst increased but applying

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pretreatment decreased the production quantities of the gases. When the corn stover was

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acid pretreated, the quantity of H2 was largely reduced from 0.04–0.05 L to 0.001–0.005

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L. It has been reported that the formation of H2 from agricultural residues by microwave

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hemicellulose or even cellulose of corn stover would be partly removed during the acid

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treatment, resulting in its lower yield of H2. In fact, all the four gases should be

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primarily generated from the hemicellulose and cellulose fractions of corn stover, so it

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is not surprising that their production quantities were reduced after acid pretreatment.

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Furthermore, the productions of H2, CH4, and CO2 were relatively small or even none

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during the first 5 min, where the reaction temperature had not yet reached the maximum

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temperature. The lower temperature means that the more gases were produced from

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components of biomass with higher thermal reactivity (i.e., hemicellulose and cellulose).

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This provides another proof that the acid pretreatment should take the responsibility for

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the reduction on H2, CH4, and CO2 yields.

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3.4 Reaction kinetics

In this study, the reaction kinetics for microwave pyrolysis of corn stover under different conditions was analyzed by using a first-order reaction model:

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dqt = k1 (qm − qt ) dt

(1)

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where k1 is the first-order reaction rate constant, qm is the maximum quantity of gaseous

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product from corn stover by microwave pyrolysis, and qt is the quantity of gaseous

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product at any time, t. The condensable gases were not considered here. By plotting

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dqt/dt versus qt, a straight line can be obtained after linear regression. The first-order

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reaction rate constant and the maximum quantity of gaseous product can be determined

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from the slope and intercept of the straight line, respectively. The result of first-order

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reaction kinetic analysis is listed in Table 1.

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Besides, a second-order reaction model was also applied:

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dqt 2 = k 2 (qm − qt ) dt

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where k2 is the second-order reaction rate constant. Integrating Eq. (2) followed by a

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rearrangement results in:

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(2)

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(3)

By plotting t/qt versus t, a straight line can be obtained after linear regression. The

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maximum quantity of gaseous product and the second-order reaction rate constant can

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be determined from the slope and intercept of the straight line, respectively. The result

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of second-order reaction kinetic analysis is listed in Table 2. Furthermore, to testify the

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accuracy of the two reaction kinetics models, the average absolute error (AAE) was

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applied [46,47]:

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AAE =

1 n qtexp − qtcal ∑ q exp × 100% n i =1 t

(4)

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where n is the number of data points, and qtexp and qtcal are experimental and calculated

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quantities of gaseous product, respectively.

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Table 2

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range of 0.83–0.91, lower than those of the second-order reaction model (0.95–0.99).

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Under different conditions, k1 and k2 are between 0.10–0.25 and 0.04–0.16, respectively.

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The maximum quantities of gaseous product determined by the two models are not very

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different. The maximum quantities determined by the first-order reaction and the

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second-order reaction models are in the ranges of 1.34–2.21 L and 1.39–2.30 L,

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respectively. Both of the models are helpful to predict the allowable maximum gaseous

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yield of microwave pyrolysis of corn stover. However, the AAE of the second-order

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reaction model is much lower than that of the first-order reaction model. Therefore, the

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reaction kinetics of gaseous production from corn stover by microwave pyrolysis can be

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better fitted by the second-order reaction model. However, it should be noted that the

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first-order reaction model and the second-order reaction model are differential and

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integral, respectively. Therefore, the different kinetic parameters and fitting errors could

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be also attributable to the different methods. Both of the models indicate that there were

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the highest reaction rate constants when the 5-mesh corn stover was microwave

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pyrolyzed with and without 50-mesh Al2O3, but the maximum quantity of gaseous

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product was lowest. These results show that the driving force of reaction may mainly

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come from the magnitude of maximum gaseous productivity. As aforementioned, the

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product distribution of microwave pyrolysis of corn stover was similar to that of

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catalytic microwave pyrolysis using 50-mesh Al2O3. Although adding 10-mesh Al2O3

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substantially reduced the reaction rate constants, the larger catalyst provided higher

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maximum quantity of gaseous product that is the primary driving force of reaction.

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There was the lowest reaction rate constant when the 40-mesh corn stover pretreated by

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steam explosion was microwave pyrolyzed with 10-mesh Al2O3. However, the effect of

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acid pretreatment on the reaction rate constant was insignificant.

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The kinetic parameters (activation energy and pre-exponential factor) of microwave pyrolysis of corn stover can be determined from the reaction rate constants

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as above mentioned and their corresponding reaction temperatures by using the

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Arrhenius equation:

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k = A exp(− Ea / RT )

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where A is the pre-exponential factor, Ea is the activation energy, R is the gas constant,

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and T is the maximum temperature. Taking natural logarithms on both sides of Eq. (5)

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leads to:

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ln k = − Ea / RT + ln A

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(6)

By plotting lnk versus T, a straight line can be obtained after linear regression. The

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second-order reaction rate constants were applied here because of their higher accuracy

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as aforementioned. The result shows that the activation energy and pre-exponential

382

factor are approximately 21 kJ/mol and 0.02 1/s, respectively, with R2 value of 0.96.

383

The activation energy of microwave pyrolysis of corn stover is similar to that of

384

microwave pyrolysis of other lignocellulosic biomass, and it is much lower than those

385

of conventional pyrolysis of various biomass feedstocks [48,49]. The pre-exponential

386

factor of microwave pyrolysis of corn stover is lower than that of microwave pyrolysis

387

of rice straw by approximately one order of magnitude [49].

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388 389

4. Conclusions

390 391

The heating efficiency and gaseous yield of microwave pyrolysis of corn stover

17

ACCEPTED MANUSCRIPT increased with decreasing particle size of corn stover. Adding catalyst or applying

393

pretreatment also promoted the reactivity of corn stover pyrolysis. According to the

394

literature, the hemicellulose and cellulose fractions of corn stover may be

395

depolymerized and hydrolyzed during acid pretreatment, resulting in less gas

396

(non-condensable part of pyrolysis product vapor) but more liquid (condensable part)

397

produced. The effect of steam explosion was not significant. A secondary reaction

398

occurred after microwave pyrolysis may exist, where the product vapor released by

399

biomass pyrolysis was entrapped by catalyst particles, and then it further decomposed

400

into light hydrocarbons (CH4, C2H4, C2H6, etc.) and permanent gases (H2, CO, and CO2).

401

However, when the catalyst particles were too small, they could be encapsulated by

402

other catalyst and biomass particles to reduce their catalytic activity. The reaction

403

kinetics of microwave pyrolysis of corn stover can be well described by a second-order

404

reaction model. The activation energy of microwave pyrolysis of corn stover is similar

405

to that of microwave pyrolysis of other lignocellulosic biomass, and it is much lower

406

than those of conventional pyrolysis of various biomass feedstocks.

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409 410

Acknowledgments

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The authors gratefully acknowledge the financial support from the Ministry of

411

Education (Project: Development of the effective production of bio-fertilizers recycled

412

from agricultural waste) and Ministry of Science and Technology, Taiwan, ROC (MOST

413

102-2221-E-131-001-MY3).

414 415

Appendix A. Supplementary material

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ACCEPTED MANUSCRIPT 416 417 418

Supplementary data associated with this article can be found, in the online version, at http://dx.doi.org/

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References

421

[1] Ragauskas AJ, Williams CK, Davison BH, Britovsek G, Cairney J, Eckert CA, et al.

SC

422

The path forward for biofuels and biomaterials. Science 2006;311:484–9.

424

[2] Tilman D , Socolow R , Foley JA , Hill J , Larson E , Lynd L , et al. Beneficial

425 426

M AN U

423

biofuels—the food, energy, and environment trilemma. Science 2009;325:270–1. [3] Himmel ME, Ding SY, Johnson DK, Adney WS, Nimlos MR, Brady JW, et al. Biomass recalcitrance: engineering plants and enzymes for biofuels production.

428

Science 2007;315:804–7.

TE D

427

[4] Luque R, Herrero-Davila L, Campelo JM, Clark JH, Hidalgo JM, Luna D, et al.

430

Biofuels: a technological perspective. Energy Environ Sci 2008;1:542–64.

431

[5] Jacobson MZ. Review of solutions to global warming, air pollution, and energy

433 434 435 436

security. Energy Environ Sci 2009;2:148–73. [6] D’Alessandro DM, Smit B, Long JR. Carbon dioxide capture: prospects for new

AC C

432

EP

429

materials. Angew Chem Int Ed 2010;49:6058–82.

[7] Chu S, Majumdar A. Opportunities and challenges for a sustainable energy future. Nature 2012;488:294–303.

437

[8] IEA. Key World Energy Statistics. Paris: International Energy Agency (IEA); 2015.

438

[9] IEA. Energy, Climate Change and Environment: 2016 Insights. Paris: International

439

Energy Agency (IEA); 2016.

19

ACCEPTED MANUSCRIPT

441 442 443 444

[10] UNEP. The Emissions Gap Report 2016. Nairobi: United Nations Environment Programme (UNEP); 2016. [11] Bridgwater AV, Peacocke GVC. Fast pyrolysis processes for biomass. Renew Sust Energ Rev 2000;4:1–73.

RI PT

440

[12] Woolf D, Amonette JE, Street-Perrott FA, Lehmann J, Joseph S. Sustainable biochar to mitigate global climate change. Nat Commun 2010;1:56.

446

doi:10.1038/ncomms1053.

449 450 451 452 453

Managing climate risk. Science 2001;294:786–7.

M AN U

448

[13] Obersteiner M, Azar C, Kauppi P, Möllersten K, Moreira J, Nilsson S, et al.

[14] Demirbas A. Progress and recent trends in biofuels. Prog Energy Combust Sci 2007;33:1–18.

[15] Yaman S. Pyrolysis of biomass to produce fuels and chemical feedstocks. Energy Convers Manage 2004;45:651–71.

TE D

447

SC

445

[16] Stöcker M. Biofuels and biomass-to-liquid fuels in the biorefinery: catalytic conversion of lignocellulosic biomass using porous materials. Angew Chem Int Ed

455

2008;47:9200–11.

457 458 459 460

[17] Gabriel C, Gabriel S, Grant EH, Halstead BSJ, Mingos DMP. Dielectric parameters relevant to microwave dielectric heating. Chem Soc Rev 1998;27:213–24.

AC C

456

EP

454

[18] Haque KE. Microwave energy for mineral treatment processes—a brief review. Int J Miner Process 1999;57:1–24.

[19] Jones DA, Lelyveld TP, Mavrofidis SD, Kingman SW, Miles NJ. Microwave

461

heating applications in environmental engineering—a review. Resour Conserv

462

Recycl 2002;34:75–90.

463

[20] Appleton TJ, Colder RI, Kingman SW, Lowndes IS, Read AG. Microwave

20

ACCEPTED MANUSCRIPT 464 465

technology for energy-efficient processing of waste. Appl Energy 2005;81:85–113. [21] Luque R, Menéndez JA, Arenillas A, Cot J. Microwave-assisted pyrolysis of biomass feedstocks: the way forward? Energy Environ Sci 2012;5:5481–8.

467

[22] Yin C. Microwave-assisted pyrolysis of biomass for liquid biofuels production.

468

RI PT

466

Bioresour Technol 2012;120:273–84.

[23] Menéndez JA, Arenillas A, Fidalgo B, Fernández Y, Zubizarreta L, Calvo EG, et al.

470

Microwave heating processes involving carbon materials. Fuel Process Technol

471

2010;91:1–8.

476 477 478 479 480 481 482 483 484 485 486 487

M AN U

475

[25] Mushtaq F, Mat R, Ani FN. A review on microwave assisted pyrolysis of coal and biomass for fuel production. Renew Sustain Energy Rev 2014;39:555–74. [26] Li J, Dai J, Liu G, Zhang H, Gao Z, Fu J, et al. Biochar from microwave pyrolysis

TE D

474

pyrolysis. Energies 2012;5:4209–32.

of biomass: A review. Biomass Bioenerg 2016;94:228–44. [27] Kim S, Dale BE. Global potential bioethanol production from wasted crops and crop residues. Biomass Bioenerg 2004;26:361–75.

EP

473

[24] Lam SS, Chase HA. A review on waste to energy processes using microwave

[28] Sokhansanj S, Turhollow A, Cushman J, Cundiff J. Engineering aspects of collecting corn stover for bioenergy. Biomass Bioenerg 2002;23:347–55.

AC C

472

SC

469

[29] Agriculture and Food Agency, Council of Agriculture, Executive Yuan, Taiwan, http://www.afa.gov.tw/.

[30] Lal R. World crop residues production and implications of its use as a biofuel. Env Intl 2005;31:575–84. [31] Balat M, Balat H, Öz C. Progress in bioethanol processing. Prog Energy Combust Sci 2008;34:551–73.

21

ACCEPTED MANUSCRIPT 488 489

[32] Zheng Y, Zhao J, Xu F, Li Y. Pretreatment of lignocellulosic biomass for enhanced biogas production. Prog Energy Combust Sci 2014;42:35–53. [33] Huang YF, Chiueh PT, Kuan WH, Lo SL. Effects of lignocellulosic composition

491

and microwave power level on the gaseous product of microwave pyrolysis.

492

Energy 2015;89:974–81.

493

RI PT

490

[34] Bu Q, Lei H, Ren S, Wang L, Holladay J, Zhang Q, et al. Phenol and phenolics

from lignocellulosic biomass by catalytic microwave pyrolysis. Bioresour Technol

495

2011;102:7004–7.

[35] Zhang S, Dong Q, Zhang L, Xiong Y. High quality syngas production from

M AN U

496

SC

494

497

microwave pyrolysis of rice husk with char-supported metallic catalysts. Bioresour

498

Technol 2015;191:17–23.

[36] Zhang B, Zhong Z, Chen P, Ruan R. Microwave-assisted catalytic fast pyrolysis of

500

biomass for bio-oil production using chemical vapor deposition modified HZSM-5

501

catalyst. Bioresour Technol 2015;197:79–84.

504 505 506 507 508

hydrogen-rich gas. Fuel Process Technol 2004;85:1201–11.

EP

503

[37] Li S, Xu S, Liu S, Yang C, Lu Q. Fast pyrolysis of biomass in free-fall reactor for

[38] Lee DH, Yang H, Yan R, Liang DT. Prediction of gaseous products from biomass pyrolysis through combined kinetic and thermodynamic simulations. Fuel

AC C

502

TE D

499

2007;86:410–7.

[39] Yang H, Yan R, Chen H, Lee DH, Zheng C. Characteristics of hemicellulose, cellulose and lignin pyrolysis. Fuel 2007;86:1781–8.

509

[40] Mosier N, Wyman C, Dale B, Elander R, Lee YY, Holtzapple M, et al. Features of

510

promising technologies for pretreatment of lignocellulosic biomass. Bioresour

511

Technol 2005;96:673–86.

22

ACCEPTED MANUSCRIPT 512

[41] Hsu TC, Guo GL, Chen WH, Hwang WS. Effect of dilute acid pretreatment of rice

513

straw on structural properties and enzymatic hydrolysis. Bioresour Technol

514

2010;101:4907–13. [42] Naik SN, Goud VV, Rout PK, Dalai AK. Production of first and second generation

RI PT

515

biofuels: A comprehensive review. Renew Sust Energ Rev 2010;14:578–97.

517

[43] Sebayang AH, Masjuki HH, Ong HC, Dharma S, Silitonga AS, Mahlia TMI, et al.

518

A perspective on bioethanol production from biomass as alternative fuel for spark

519

ignition engine. RSC Adv 2016;6:14964–92.

[44] Lim JS, Manan ZA, Alwi SRW, Hashim H. A review on utilisation of biomass from

M AN U

520

SC

516

521

rice industry as a source of renewable energy. Renew Sust Energ Rev

522

2012;16:3084–94.

523

[45] Dagnino EP, Chamorro ER, Romano SD, Felissia FE, Area MC. Optimization of the acid pretreatment of rice hulls to obtain fermentable sugars for bioethanol

525

production. Ind Crop Prod 2013;42:363–8.

528 529 530 531 532 533

proximate analysis of solid fuels. Fuel 2005;84:487–94.

EP

527

[46] Parikh J, Channiwala SA, Ghosal GK. A correlation for calculating HHV from

[47] Sheng C, Azevedo JLT. Estimating the higher heating value of biomass fuels from basic analysis data. Biomass Bioenerg 2005;28:499–507.

AC C

526

TE D

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[48] Dong Q, Xiong YQ. Kinetics study on conventional and microwave pyrolysis of moso bamboo. Bioresour Technol 2014;171:127–31.

[49] Huang YF, Chiueh PT, Kuan WH, Lo SL. Microwave pyrolysis of lignocellulosic biomass: Heating performance and reaction kinetics. Energy 2016;100:137–44.

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Figure captions

537 538

Fig. 1. Temperature profiles of (a) microwave pyrolysis of corn stover with different particle sizes and (b) catalytic microwave pyrolysis of pretreated 40 mesh corn

540

stover (AP: acid pretreatment; SE: steam explosion; NP: no pretreatment; AC:

541

adding catalyst; NC: no catalyst).

RI PT

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544

Fig. 2. Maximum temperatures (a) and heating rates (b) of microwave pyrolysis of corn stover under various conditions.

M AN U

543

545 546

SC

542

Fig. 3. Product distributions of microwave pyrolysis of corn stover: (a) no catalyst, (b) adding 10-mesh Al2O3, (c) adding 50-mesh Al2O3, (d) 40-mesh corn stover

548

with and without pretreatment and catalysis.

551 552 553 554 555 556

Fig. 4. Decomposition of product vapor of catalytic pyrolysis in comparison with conventional pyrolysis.

EP

550

Fig. 5. Production of (a) H2, (b) CH4, (c) CO2, and (d) CO from corn stover by

AC C

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547

microwave pyrolysis at different time intervals.

24

ACCEPTED MANUSCRIPT 557

Table 1

558

First-order reaction kinetic analysis of gaseous product from corn stover by microwave

559

pyrolysis. Catalysis (Al2O3)

k1 (1/min)

qm (L)

5 mesh

–

–

0.25

1.37

10 mesh

–

–

0.18

1.61

40 mesh

–

–

0.12

2.21

60 mesh

–

–

0.14

100 mesh

–

–

0.14

5 mesh

–

10 mesh

10 mesh

–

40 mesh

AAE* (%) 25.21

0.84

27.18

0.89

27.24

2.21

0.88

27.46

2.02

0.87

27.49

0.14

1.72

0.88

27.39

10 mesh

0.15

1.92

0.86

27.55

–

10 mesh

0.15

1.96

0.90

27.42

60 mesh

–

10 mesh

0.13

2.00

0.88

27.41

100 mesh

–

10 mesh

0.12

2.13

0.88

27.17

5 mesh

–

50 mesh

0.25

1.35

0.89

25.26

10 mesh

–

50 mesh

0.20

1.34

0.87

26.66

M AN U

EP –

50 mesh

0.16

1.79

0.88

27.45

–

50 mesh

0.16

1.83

0.88

27.48

AC C

60 mesh

SC

0.86

40 mesh

560

R2

RI PT

Pretreat ment

TE D

Particle size of corn stover

100 mesh

–

50 mesh

0.12

2.11

0.85

27.22

40 mesh

SE

–

0.11

2.06

0.91

26.57

40 mesh

SE

10 mesh

0.10

2.17

0.83

26.64

40 mesh

AP

–

0.13

1.74

0.88

27.33

40 mesh

AP

10 mesh

0.15

1.60

0.90

27.43

*AAE: average absolute error.

561

25

ACCEPTED MANUSCRIPT 562

Table 2

563

Second-order reaction kinetic analysis of gaseous product from corn stover by

564

microwave pyrolysis. Catalysis (Al2O3)

k2 (1/min·L)

qm (L)

5 mesh

–

–

0.15

1.42

10 mesh

–

–

0.10

1.67

40 mesh

–

–

0.05

2.30

60 mesh

–

–

0.05

100 mesh

–

–

0.06

5 mesh

–

10 mesh

10 mesh

–

40 mesh

AAE* (%) 4.42

0.98

5.33

0.98

4.55

2.30

0.98

4.71

2.10

0.97

4.93

0.07

1.78

0.98

4.58

10 mesh

0.07

2.00

0.97

5.09

–

10 mesh

0.07

2.03

0.98

3.76

60 mesh

–

10 mesh

0.06

2.08

0.97

4.83

100 mesh

–

10 mesh

0.05

2.22

0.97

4.74

5 mesh

–

50 mesh

0.16

1.39

0.99

3.95

10 mesh

–

50 mesh

0.13

1.39

0.98

4.53

M AN U

EP –

50 mesh

0.08

1.86

0.98

4.62

–

50 mesh

0.07

1.90

0.98

4.67

AC C

60 mesh

SC

0.99

40 mesh

565

R2

RI PT

Pretreat ment

TE D

Particle size of corn stover

100 mesh

–

50 mesh

0.05

2.19

0.96

5.37

40 mesh

SE

–

0.05

2.14

0.98

3.95

40 mesh

SE

10 mesh

0.04

2.26

0.95

5.83

40 mesh

AP

–

0.06

1.81

0.97

4.86

40 mesh

AP

10 mesh

0.08

1.65

0.98

4.41

*AAE: average absolute error.

566

26

569 570 571 572

EP

568

Fig. 1. Temperature profiles of (a) microwave pyrolysis of corn stover with different particle sizes and (b) catalytic microwave pyrolysis of pretreated 40 mesh corn

AC C

567

TE D

M AN U

SC

RI PT

ACCEPTED MANUSCRIPT

stover (AP: acid pretreatment; SE: steam explosion; NP: no pretreatment; AC: adding catalyst; NC: no catalyst).

573

27

M AN U

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ACCEPTED MANUSCRIPT

577 578

corn stover under various conditions.

EP

576

Fig. 2. Maximum temperatures (a) and heating rates (b) of microwave pyrolysis of

AC C

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574

28

579 580

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Fig. 3. Product distributions of microwave pyrolysis of corn stover: (a) no catalyst, (b)

581

adding 10-mesh Al2O3, (c) adding 50-mesh Al2O3, (d) 40-mesh corn stover

582

with and without pretreatment and catalysis.

583

29

RI PT

ACCEPTED MANUSCRIPT

586

Fig. 4. Decomposition of product vapor of catalytic pyrolysis in comparison with conventional pyrolysis.

587

AC C

EP

TE D

588

M AN U

585

SC

584

30

589 590 591

AC C

EP

TE D

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ACCEPTED MANUSCRIPT

Fig. 5. Production of (a) H2, (b) CH4, (c) CO2, and (d) CO from corn stover by microwave pyrolysis at different time intervals.

592

31

ACCEPTED MANUSCRIPT Highlights:

Gaseous yield increased with decreasing particle size of corn stover.




Catalytic effect was not found when catalyst particles were small.




Liquid yield was increased when acid pretreatment was applied.

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