Carbon nanotubes supported platinum–gold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction

Carbon nanotubes supported platinum–gold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction

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Carbon nanotubes supported platinumegold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction Shu-He Han a,1, Yi-Gang Ji b,1, Shi-Hui Xing a, Jiao-Jiao Hui a, Qi Guo b, Feng Shi a,*, Pei Chen a,**, Yu Chen a a

School of Materials Science and Engineering, Shaanxi Normal University, Xi'an 710062, PR China Jiangsu Key Laboratory of Biofuction Molecule, Department of Life Sciences and Chemistry, Jiangsu Second Normal University, Nanjing 210013, PR China

b

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abstract

Article history:

Improving the electrocatalytic activity, durability, and utilization of anode eletrocatalysts

Received 28 July 2016

are crucial for accelerating commercialization of direct formic acid fuel cells. In this work,

Received in revised form

the multiwall carbon nanotubes (MWCNTs) supported PtAu alloy nanocrystals (MWCNTs/

24 August 2016

PtAu) composites are synthesized by a one-pot wet-chemical method using poly-

Accepted 5 September 2016

ethyleneimine as the complexant and surfactant. The physicochemical properties of the

Available online xxx

as-prepared MWCNTs/PtAu composites are characterized detailedly by X-ray diffraction, transmission electron microscopy, scanning electron microscopy, and X-ray photoelectron

Keywords:

spectroscopy, etc. These structural investigations display the PtAu alloy nanocrystals are

PtAu alloy

highly dispersed on the surface of the MWCNTs. Cyclic voltammetry and chro-

Carbon nanotubes

noamperometry measurements show the as-prepared MWCNTs/PtAu composites signifi-

Formic acid

cantly enhance the direct dehydrogenation pathway of the formic acid oxidation reaction,

Electrooxidation

resulting in the improved electocatalytic activity and durability for the formic acid

Reaction pathway

electrooxidation. © 2016 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Introduction In comparison with direct alcohol (methanol and ethanol) fuel cells, direct formic acid fuel cells (DFAFCs) have obvious advantages, including the bigger open-circuit potential, higher specific energy density, and lower fuel crossover, etc [1e6]. So far, Pd-based nanocrystals are the most efficient and active electrocatalysts for the formic acid oxidation reaction (FAOR)

due to the dominant direct dehydrogenation pathway on the Pd surface (eq. (1)) [7e10]. However, Pd-based nanocrystals suffer from the low durability due to the Pd dissolution in the strong acidic solution with strong corrosivity, resulting in the rapid degradation of the DFAFCs performance. Pathway1 : HCOOH/HCOOads þ Hþ þ e /CO2 þ 2Hþ þ 2e (1)

* Corresponding author. ** Corresponding author. E-mail addresses: [email protected] (F. Shi), [email protected] (P. Chen). 1 These two authors made an equal contribution to this work. http://dx.doi.org/10.1016/j.ijhydene.2016.09.026 0360-3199/© 2016 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved. Please cite this article in press as: Han S-H, et al., Carbon nanotubes supported platinumegold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction, International Journal of Hydrogen Energy (2016), http://dx.doi.org/10.1016/ j.ijhydene.2016.09.026

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Pathway2 : HCOOH/COads þ H2 O/CO2 þ 2Hþ þ 2e

(2)

Although pure Pt meal has very excellent tolerance to acidic solution, the previous investigation have demonstrated the indirect dehydration pathway with COads intermediate (eq. (2)) preferentially occurs on the pure Pt surface, which results in very low reactivity for the FAOR [11,12]. Fortunately, the direct dehydrogenation pathway of the FAOR on the Pt surface (eq. (1)) can be enhanced remarkably by alloying Pt with second metal element due to the ensemble effect [13e33]. Thus, the high active and stable Pt-based bimetallic/trimetallic nanocrystals have been widely exploited as the efficient Pdalternative elelctrocatalysts for the FAOR [13e26,29e33]. Besides the reactivity and durability, improving the utilization of noble metal anode eletrocatalyst is also a key issue for accelerating commercialization of the DFAFCs. The numerous investigations have indicated that carbon nanomaterials can effectively serve as supporting materials to disperse Pt nanocrystals and improve their electrocatalytic efficiency [34e39]. At present, carbon nanotubes (CNTs), a relatively new carbon nanomaterial, have been widely used as supporting material due to their unique one-dimensional structure, high surface area, and fascinating electrical/mechanical properties, which improve the utilization of noble Pt metal [40e48]. Among various Pt-based bimetallic/trimetallic nanocrystals, PtAu bimetallic nanocrystals have been considered as highly competitive candidate for the FAOR due to their high activity and excellent durability [49e59]. At present, to our best knowledge, there are only two reports on decorating PtAu alloy nanocrystals on CNTs for the FAOR [60,61]. However, these reported PtAu/CNTs composites can't effectively enhance the direct dehydrogenation pathway of the FAOR, resulting in the low reactivity for the FAOR yet. In this work, we successfully synthesized highly dispersed multiwall carbon nanotubes (MWCNTs) supported PtAu alloy nanocrystals (MWCNTs/PtAu) composites with assistance of polyethyleneimine (PEI, Scheme S1), which effectively electrocatalyzed FAOR through the direct dehydrogenation pathway and displayed an increase in mass activity by a factor of 12.2 compared to commercial Pt/C electrocatalyst.

deionized water and stirred for 20 min. Then, 7.1 mg of MWCNTs was added into the mixture solution with ultrasonic treatment for 30 min. Subsequently, 5 mL of 0.15 M NaBH4 aqueous solution was added into the mixture solution and stirred for 60 min. After reaction, the obtained MWCNTs/PtAu composites were separated by centrifugation, washed with deionized water, and then dried in a vacuum at 40  C for 24 h. Using similar procedure, MWCNTs/Au, and MWCNTs/Pt composites were also synthesized.

Electrochemical measurements Electrochemical tests were performed on a CHI 660 D electrochemical analyzer at 30  C. Platinum wire, saturated calomel electrode (SCE), and catalyst modified glassy carbon electrode (GCE) were used as the counter electrode, reference electrode, and working electrode, respectively. Potentials in this work were reported with respect to the SCE. The working electrode was prepared according to the procedure reported previously [62,63]. The 6 mL of 2 mg mL1 catalyst ink was spread on the GCE with 3 mm diameter. Then, 3.5 mL Nafion (5 wt.%) was coated onto GCE surface. The electrochemically active surface area (ECSA) of electrocatalyst was measured in H2SO4 by integrating hydrogen adsorption charge and assuming a value of 210 mC cm2 for the monolayer Had atoms on the Pt surface [64].

Instruments The interactions between PEI and metal ions were investigated by Ultraviolet and visible spectroscopy (UVevis, Shimadzu UV-2600U). The chemical composition, surface charge, crystal structure, and morphology of the catalysts were characterized by inductively coupled plasma atomic emission spectrometry (ICP-AES, Leeman), energy dispersive X-ray spectroscopy (EDX, JSM-2010), X-ray photoelectron spectroscopy (XPS, AXIS ULTRA), zeta potential analyzer (Malvern Zetasizer Nano ZS90), X-ray diffraction (XRD, D/max-rC X-ray diffractometer), scanning electron microscopy (SEM, JSM2010), transmission electron microscopy (TEM, JEM-2100F), and high angle annular dark-field scanning TEM (HAADFSTEM, JEM-2100F). The binding energy was calibrated by means of the C 1s peak energy of 284.5 eV.

Experimental Reagents and chemicals

Results and discussion

The highly pure carboxylated MWCNTs (outer diameter: 30e50 nm; surface area: >30 m2 g1) were purchased from Chengdu Organic Chemicals Co. Ltd, Chinese Academy of Sciences. Polyethyleneimine (PEI, Scheme S1, Mw ¼ 600) was purchased from Aladdin Industrial Corporation. Commercial 40 wt. % Pt/C elelctrocatalyst was supplied from Johnson Matthey Corporation. Other reagents were of analytical reagent grade and used without further purification.

Characterization of MWCNTs/PtAu composites

Preparation of MWCNTs/PtAu composites 0.25 mL of 0.02 M H2PtCl6, 0.4 mL of 0.05 M HAuCl4, and 0.5 mL of 0.5 M PEI aqueous solutions were added into the 8.0 mL

The chemical composition of MWCNTs/PtAu composites was analyzed by ICP-AES. MWCNTs/PtAu composites contain about 7.4 wt.% Pt and 29.8 wt.% Au, which is close to its theoretical metal loading (40 wt.%). Fig. 1A shows the EDX spectrum of MWCNTs/PtAu composites. Pt/Au atomic ratio is measured to be 1:4.1, which is close to ICP-AES result (1:3.9). These experimental data demonstrate that the H2PtCl6 and HAuCl4 precursors are reduced completely by NaBH4. Fig. 1B shows XRD patterns of MWCNTs/Au, MWCNTs/PtAu, and MWCNTs/Pt composites. All composites show a characteristic C{002} diffraction peak at 25.9 , and a typical face-centered

Please cite this article in press as: Han S-H, et al., Carbon nanotubes supported platinumegold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction, International Journal of Hydrogen Energy (2016), http://dx.doi.org/10.1016/ j.ijhydene.2016.09.026

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Fig. 1 e (A) EDX spectrum of MWCNTs/PtAu composites. (B) XRD patterns of (a) MWCNTs/Au, (b) MWCNTs/PtAu, and (c) MWCNTs/Pt composites.

cubic (fcc) structure. For MWCNTs/PtAu composites, the four characteristic fcc diffraction peak are located at the position between the corresponding Au diffraction peaks at MWCNTs/ Au composites and Pt diffraction peaks at MWCNTs/Pt composites, indicating the formation of PtAu alloy. The particle size of the deposited PtAu alloy nanoparticles was estimated to be 3.2 nm according to Scherrer's formula. In the absence of PEI, the weak diffraction peaks of Pt are observed at the obtained MWCNTs/PtAu composites (Fig. S1), indicating the low alloying degree. The control experiment clearly demonstrates the existence of PEI facilitates the formation of PtAu alloy. In order to explore the reason, UVevis and linear sweep voltammetry measurements were carried out. Upon the addition of PEI solution in H2PtCl6 or HAuCl4 solution, their UVevis spectra change obviously (Fig. S2), indicating the formation of PEIePtIV and PEIeAuIII complexes, respectively [65]. Linear sweep voltammetry measurements show the existence of PEI can effectively decrease the reduction potentials of both H2PtCl6 and HAuCl4 due to the coordination interaction, and the reduction potential of PEIePtIV complex is close to that of PEIeAuIII complex (Fig. S3). The similarity in reduction potentials allows PtIV and AuIII precursors to be reduced simultaneously by NaBH4, resulting in the generation of PtAu alloy. The morphology and structure of MWCNTs/PtAu composites were evaluated by TEM. Fig. 2A shows TEM images of MWCNTs/PtAu composites. As observed, the spherical PtAu alloy nanocrystals with the average size of 3.42 nm are highly dispersed on the MWCNTs surface. In a control experiment without PEI, the obtained MWCNTs/PteAu composites generate the obvious aggregation (Fig. S4). This fact suggests the PEI effectively acts as surfactant to inhibit the aggregation of PtAu alloy nanocrystals due to its bulky molecule volume and excellent hydrophilic property [64,66]. The carboxylated MWCNTs is negatively charged (zeta potential: e28.2 mV) whereas both PEIePtIV and PEIeAuIII complexes are positively charged due to the protonation of eNH2 groups [64,66]. Thus, the efficient anchorage of PEIePtIV and PEIeAuIII complexes on carboxylated MWCNTs via electrostatic interaction also contributes to the well dispersion of PtAu alloy nanocrystals on the surface of MWCNTs [64]. Fig. 2B shows the HAADF-STEM image and corresponding EDX element mapping patterns of MWCNTs/PtAu composites. The EDX element mapping patterns show Pt, Au, and C elements evenly distribute on the

same region, further confirming the uniform distribution of PtAu alloy nanocrystals on the surface of MWCNTs. Meanwhile, the N element is also detected, demonstrating the existence of PEI. The appearance of the characteristic N1s XPS peak further confirms the existence of PEI at MWCNTs/PtAu composites (Fig. S5), which originates from the anchorage of PEI on both MWCNTs and PtAu nanocrystals due to electrostatic interaction and N-metal bond interaction, respectively [64]. Fig. 2C shows SEM image of MWCNTs/PtAu composites. As observed, MWCNTs/PtAu composites have threedimensionally and highly porous architecture. Such interconnected structure not only provides effectively continuous transport pathway of electron but also accelerates mass transport of reactant [40e48]. Fig. 2D shows high-resolution TEM (HRTEM) image of MWCNTs/PtAu composites. HRTEM image displays the clear lattice fingers. Fig. 2E shows the magnified HRTEM images. The magnified HRTEM images show the interval distance between adjacent lattice fringes is 0.230 nm. This value is larger than the {111} lattice spacing (0.226 nm) of the fcc Pt crystal but is smaller than that (0.235 nm) of the fcc Au crystal, further confirming the formation of PtAu alloy. The corresponding fast Fourier transform (FFT) patterns show the spot patterns with 6-fold rotational symmetry, implying the PtAu alloy nanocrystals at MWCNTs/PtAu composites are presented by {111} facets. The surface composition and electronic structure of MWCNTs/PtAu composites were analyzed by XPS. Fig. 3 shows Pt 4f and Au 4f XPS spectra of MWCNTs/PtAu composites. XPS data display Pt/Au atomic ratio is 1:3.4, which is close to ICPAES and EDX data. These experimental results demonstrate the similar chemical composition exists at bulk and surface, which is indicative of PtAu alloy formation. Meanwhile, it is observed that both Pt 4f and Au 4f binding energies of MWCNTs/PtAu composites exhibit 0.2 and 0.1 eV negative shift compared to the standard values of bulk Pt and Au [67], respectively. Obviously, the interaction between Pt and Au elements can't explain the phenomenon. Therefore, the strong electron donation must come from other places at MWCNTs/PtAu composites. The XPS and EDX mapping measurements have demonstrated the existence of PEI in MWCNTs/PtAu composites. The lone pair electrons of eNH2 groups at PEI can efficiently donate electrons to Pt and Au atoms due to strong NePt and NeAu bonds [64e66], which

Please cite this article in press as: Han S-H, et al., Carbon nanotubes supported platinumegold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction, International Journal of Hydrogen Energy (2016), http://dx.doi.org/10.1016/ j.ijhydene.2016.09.026

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Fig. 2 e (A) Typical TEM images of MWCNTs/PtAu composites. Insert: the corresponding size distribution histogram. (B) HAADF-STEM image and corresponding EDX element mapping patterns of MWCNTs/PtAu composites. (C) Representative SEM image of MWCNTs/PtAu composites. (D) Typical HRTEM image of MWCNTs/PtAu composites. (E) The magnified HRTEM images recorded from region marked by blue and green squares in D and the corresponding FFT patterns. (For interpretation of the references to colour in this figure legend, the reader is referred to the web version of this article.)

Fig. 3 e (A) Pt 4f and (B) Au 4f XPS spectra of MWCNTs/PtAu composites. The vertical black dotted lines in Fig. 3A and B represent the standard values of Pt 4f7/2 and Au 4f7/2, respectively.

Please cite this article in press as: Han S-H, et al., Carbon nanotubes supported platinumegold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction, International Journal of Hydrogen Energy (2016), http://dx.doi.org/10.1016/ j.ijhydene.2016.09.026

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leads to the negative shift in both Pt 4f and Au 4f binding energies.

Electrocatalytic performance measurements The electrochemical property of MWCNTs/PtAu composites was investigated and compared to commercial 40 wt.% Pt/C electrocatalyst by cyclic voltammetry (CV). Fig. 4 shows the CV curves of MWCNTs/PtAu composites and commercial Pt/C electrocatalyst. The ECSA of MWCNTs/PtAu composites and commercial Pt/C electrocatalyst are calculated to be 56.8 and 43.6 m2 g1 Pt . Although the mean particle size of MWCNTs/PtAu composites (ca. 3.5 nm) is bigger than that of commercial Pt/C electrocatalyst (ca. 2.4 nm, Fig. S6), the ECSA of MWCNTs/PtAu composites is comparable to that of commercial Pt/C electrocatalyst. This fact demonstrates that three-dimensionally and porous architecture of MWCNTs/PtAu composites facilitates the mass transfer of reactant during the electrochemical reaction. The electrocatalytic activities of MWCNTs/PtAu composites and Pt/C electrocatalyst were evaluated by CV. Fig. 5A shows the CV curves of MWCNTs/PtAu composites and commercial Pt/C electrocatalyst during the FAOR. In general, the FAOR on Pt-based nanocrystals obeys a dual-path mechanism that involves a dehydrogenation pathway (direct pathway) without COads poisoning intermediate and a dehydration

Fig. 4 e CV curves of (a) MWCNTs/PtAu composites and (b) commercial Pt/C electrocatalyst in N2-saturated 0.5 M H2SO4 solution at 50 mV s¡1.

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pathway (indirect pathway) with COads poisoning intermediate (eqs. (1) and (2)) [13e26,68e70]. The oxidation peaks of the FAOR at both electrocatalysts appear at 0.30 and 0.70 V in the forward and backward sweeps, corresponding to the direct oxidation and indirect oxidation of formic acid, respectively. The reaction pathway of the FAOR is determined by atomic arrangement of Pt-based nanocrystals. Compared to MWCNTs/Pt composites and MWCNTs/Au composites, MWCNTs/PtAu composites show improved FAOR activity (Fig. S7), indicating the single isolated Pt atom can effectively enhance the direct pathway of the FAOR [13e26,68e70]. For MWCNTs/PtAu composites, the oxidation peak of the FAOR via direct pathway at 0.3 V is enhanced significantly, in comparison with commercial Pt/C electrocatalyst. ECSAnormalized CV curves also reveal that specific activity of MWCNTs/PtAu composites is much better than that of commercial Pt/C electrocatalyst (Fig. S8). These facts indicate the FAOR on MWCNTs/PtAu composites proceeds dominantly through direct pathway due to the formation of PtAu alloy. At 0.3 V potential, Pt-mass activities of MWCNTs/PtAu composites and commercial Pt/C electrocatalyst for the FAOR are 1345 1 A g1 Pt and 110 A gPt , showing the improved reactivity of MWCNTs/PtAu composites. Meanwhile, the Pt-mass activity (1345 A g1 Pt ) of MWCNTs/PtAu composites for the FAOR at 0.3 V is also much higher than reported values of various Pt-based nanocrystals, such as PtPb nanoflowers (310 A g1 Pt ) [21], Pt/ graphene hybrids (280 A g1 Pt ) [64], PtAgCu@PtCu concave nanooctahedrons (320 A g1 Pt ) [22], Pt/Ni(OH)2eNiOOH/Pd multi-walled hollow nanorod arrays (500 A g1 Pt ) [71], and Pt1Au3 nanowires (1180 A gPt1) [72], Pt1Au8/graphene (570 A gPt1) [73], Pt10Au1 nanodendrites (170 A g1 Pt ) [57], which further confirm the high FAOR activity and high Pt utilization of MWCNTs/PtAu composites. Considering that Au is an expensive metal, metal-mass normalized CV curves were also investigated (Fig. S9). As observed, the metal-mass activity of MWCNTs/PtAu composites is still 3.03 times bigger than that of commercial Pt/C electrocatalyst at 0.3 V potential, indicating the promising practical application. It is well known that the electrocatalytic activity of electrocatalyst highly relates to its chemical composition [74,75]. Thus, the electrocatalytic activities of MWCNTs/PtAu composites with different PtAu atomic ratio for the FAOR were investigated (Fig. S10). As observed, Pt-mass activity of MWCNTs/PtAu

Fig. 5 e (A) Pt-mass normalized CV curves of (a) MWCNTs/PtAu composites and (b) commercial Pt/C electrocatalyst in N2saturated 0.5 M H2SO4 þ 0.5 M HCOOH solution at 50 mV s¡1. (B) CA curves of (a) MWCNTs/PtAu composites and (b) commercial Pt/C electrocatalyst in N2-saturated 0.5 M H2SO4 þ 0.5 M HCOOH solution for 6000 s at 0.30 V potential. Please cite this article in press as: Han S-H, et al., Carbon nanotubes supported platinumegold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction, International Journal of Hydrogen Energy (2016), http://dx.doi.org/10.1016/ j.ijhydene.2016.09.026

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composites at 0.3 V potential gradually increases with increasing Au amount. When AuPt atomic ratio reaches to 4:1, the Pt-mass activity of the MWCNTs/PtAu composites reaches a maximum and then retain constant after further increasing AuPt atomic ratio to 5:1. The durability of electrocatalysts is very critical for fuel cells application. Fig. 5B shows the chronoamperometry (CA) curves of MWCNTs/PtAu composites and commercial Pt/C electrocatalyst for the FAOR. As observed, the currents of the FAOR at both MWCNTs/PtAu composites and commercial Pt/C electrocatalyst decrease gradually. However, the current at MWCNTs/PtAu composites decreases more slowly as compared with commercial Pt/C electrocatalyst. For example, at 6000 s, the current of the FAOR at MWCNTs/PtAu composites remains 30.5% of their initial value at 20 s [7,8,76], which is much better than that (20.6%) at Pt/C electrocatalyst. Meanwhile, MWCNTs/PtAu composites exhibit higher current than commercial Pt/C electrocatalyst over the entire reaction time, also confirming the improved durability of MWCNTs/PtAu composites. On the one hand, the formation of PtAu alloy interrupts the contiguous Pt atoms, resulting in ensemble effect that enhances direct pathway of the FAOR. On the other hand, the negative shift of Pt binding energies also facilitate the direct pathway of the FAOR due to the electronic effect [13,21]. The enhanced direct pathway effectively decreases the COads poisoning effect, which contributes to the improved durability of MWCNTs/PtAu composites for the FAOR.

Conclusions We have developed a facile one-pot wet-chemical method for the preparation of high-quality MWCNTs/PtAu composites with the assistance of PEI. Due to the particular coordination interactions, PEI efficiently decreases the reduction potential difference between H2PtCl6/Pt and HAuCl4/Au redox pairs, resulting in the formation of PtAu alloy. Meanwhile, PEI effectively serves as surfactant to restrain the aggregation of PtAu alloy nanocrystals, resulting in small particle size and excellent dispersion of PtAu alloy nanocrystals on the MWCNTs surface. Based on the ensemble effect and electronic effect, MWCNTs/PtAu composites significantly enhance the direct pathway of the FAOR, resulting in the superior electocatalytic mass activity for the FAOR. In particular, MWCNTs/ PtAu composites also show the excellent durability for the FAOR due to the enhanced direct pathway. With high mass activity and good durability, the as-prepared MWCNTs/PtAu composites may have potential application in the DFAFCs.

Acknowledgments This research was sponsored by Natural Science Foundation of Shaanxi Province (2015JM2043), Doctoral Program of Higher Education of China (20130202120010), Key Science and Technology Program of Shaanxi Province (2014K1006), and Fundamental Research Funds for the Central Universities (GK201602002 and GK201503036).

Appendix A. Supplementary data Supplementary data related to this article can be found at http://dx.doi.org/10.1016/j.ijhydene.2016.09.026.

references

[1] Joo J, Choun M, Jeong J, Lee J. Influence of solution pH on Pt anode catalyst in direct formic acid fuel cells. ACS Catal 2015;5:6848e51. [2] Hu S, Munoz F, Noborikawa J, Haan J, Scudiero L, Ha S. Carbon supported Pd-based bimetallic and trimetallic catalyst for formic acid electrochemical oxidation. Appl Catal B-Environ 2016;180:758e65. [3] Fathirad F, Afzali D, Mostafavi A. Bimetallic PdeZn nanoalloys supported on Vulcan XC-72R carbon as anode catalysts for oxidation process in formic acid fuel cell. Int J Hydrogen Energy 2016;41:13220e6. [4] Mao H, Huang T, Yu A. Electrochemical surface modification on CuPdAu/C with extraordinary behavior toward formic acid/formate oxidation. Int J Hydrogen Energy 2016;41:13190e6. [5] Yang F, Zhang Y, Liu P-F, Cui Y, Ge X-R, Jing Q-S. Pd-Cu alloy with hierarchical network structure as enhanced electrocatalysts for formic acid oxidation. Int J Hydrogen Energy 2016;41:6773e80. [6] Hao Y, Shen J, Wang X, Yuan J, Shao Y, Niu L, et al. Facile preparation of PdIr alloy nano-electrocatalysts supported on carbon nanotubes, and their enhanced performance in the electro-oxidation of formic acid. Int J Hydrogen Energy 2016;41:3015e22. [7] Zhang L, Wan L, Ma Y, Chen Y, Zhou Y, Tang Y, et al. Crystalline palladium-cobalt alloy nanoassemblies with enhanced activity and stability for the formic acid oxidation reaction. Appl Catal B-Environ 2013;138:229e35. [8] Sun D, Si L, Fu G, Liu C, Sun D, Chen Y, et al. Nanobranched porous palladium-tin intermetallics: one-step synthesis and their superior electrocatalysis towards formic acid oxidation. J Power Sources 2015;280:141e6. [9] Maiyalagan T, Wang X, Manthiram A. Highly active Pd and Pd-Au nanoparticles supported on functionalized graphene nanoplatelets for enhanced formic acid oxidation. RSC Adv 2014;4:4028e33. [10] Mert SO, Reis A. Exergoeconomic analysis of a direct formic acid fuel cell system. Int J Hydrogen Energy 2016;41:2981e6. [11] Xu Y, Zhang B. Recent advances in porous Pt-based nanostructures: synthesis and electrochemical applications. Chem Soc Rev 2014;43:2439e50. [12] Yang S, Lee H. Atomically dispersed platinum on gold nanooctahedra with high catalytic activity on formic acid oxidation. ACS Catal 2013;3:437e43. [13] Peng Z, You H, Yang H. An electrochemical approach to PtAg alloy nanostructures rich in Pt at the surface. Adv Funct Mater 2010;20:3734e41. [14] Cui Z, Yang M, DiSalvo FJ. Mesoporous Ti0.5Cr0.5N supported PdAg nanoalloy as highly active and stable catalysts for the electro-oxidation of formic acid and methanol. ACS nano 2014;8:6106e13. [15] Xu Y, Hou S, Liu Y, Zhang Y, Wang H, Zhang B. Facile onestep room-temperature synthesis of Pt3Ni nanoparticle networks with improved electro-catalytic properties. Chem Commun 2012;48:2665e7. [16] Kang Y, Murray CB. Synthesis and electrocatalytic properties of cubic MnPt nanocrystals (nanocubes). J Am Chem Soc 2010;132:7568e9.

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[17] Ge X, Chen L, Kang J, Fujita T, Hirata A, Zhang W, et al. A core-shell nanoporous Pt-Cu catalyst with tunable composition and high catalytic activity. Adv Funct Mater 2013;23:4156e62. [18] Zhang J, Yang H, Martens B, Luo Z, Xu D, Wang Y, et al. Pt-Cu nanoctahedra: synthesis and comparative study with nanocubes on their electrochemical catalytic performance. Chem Sci 2012;3:3302e6. [19] Nosheen F, Zhang ZC, Zhuang J, Wang X. One-pot fabrication of single-crystalline octahedral Pt-Cu nanoframes and their enhanced electrocatalytic activity. Nanoscale 2013;5:3660e3. [20] Xu D, Bliznakov S, Liu ZP, Fang JY, Dimitrov N. Compositiondependent electrocatalytic activity of Pt-Cu nanocube catalysts for formic acid oxidation. Angew Chem Int Ed 2010;49:1282e5. [21] Gong M, Li F, Yao Z, Zhang S, Dong J, Chen Y, et al. Highly active and durable platinum-lead bimetallic alloy nanoflowers for formic acid electrooxidation. Nanoscale 2015;7:4894e9. [22] Fu G-T, Xia B-Y, Ma R-G, Chen Y, Tang Y-W, Lee J-M. Trimetallic PtAgCu@PtCu core@shell concave nanooctahedrons with enhanced activity for formic acid oxidation reaction. Nano Energy 2015;12:824e32. [23] Awaludin Z, Okajima T, Ohsaka T. Formation of Pt-Li alloy and its activity towards formic acid oxidation. Electrochem Commun 2013;31:100e3. [24] Kang Y, Qi L, Li M, Diaz RE, Su D, Adzic RR, et al. Highly active Pt3Pb and core-shell Pt3Pb-Pt electrocatalysts for formic acid oxidation. ACS Nano 2012;6:2818e25. [25] Huang Z, Liu Y, Xie F, Fu Y, He Y, Ma M, et al. Au-supported Pt-Au mixed atomic monolayer electrocatalyst with ultrahigh specific activity for oxidation of formic acid in acidic solution. Chem Commun 2012;48:12106e8. [26] Buzzo GS, Orlandi MJB, Teixeira-Neto E, Homem-de-Mello P, Lopes ACG, Franco-Junior E, et al. Effects of catalyst load in Pt and Pb-based catalysts using formic acid oxidation as a model. J Power Sources 2012;199:75e84. [27] Li D, Meng F, Wang H, Jiang X, Zhu Y. Nanoporous AuPt alloy with low Pt content: a remarkable electrocatalyst with enhanced activity towards formic acid electro-oxidation. Electrochim Acta 2016;190:852e61. [28] Dutta S, Ray C, Sarkar S, Roy A, Sahoo R, Pal T. Facile synthesis of bimetallic Au-Pt, Pd-Pt, and Au-Pd nanostructures: enhanced catalytic performance of Pd-Pt analogue towards fuel cell application and electrochemical sensing. Electrochim Acta 2015;180:1075e84. [29] Zhang J-M, Wang R-X, Nong R-J, Li Y, Zhang X-J, Zhang P-Y, et al. Hydrogen co-reduction synthesis of PdPtNi alloy nanoparticles on carbon nanotubes as enhanced catalyst for formic acid electrooxidation. Int J Hydrogen Energy 2016. http://dx.doi.org/10.1016/j.ijhydene.2016.05.198. [30] Mohammad AM, El-Nagar GA, Al-Akraa IM, El-Deab MS, ElAnadouli BE. Towards improving the catalytic activity and stability of platinum-based anodes in direct formic acid fuel cells. Int J Hydrogen Energy 2015;40:7808e16. [31] Hosseini SR, Hosseinzadeh R, Ghasemi S, Farzaneh N. Synthesis of poly (2-Methoxyaniline)/sodium dodecyl sulfate film including bimetallic Pt-Cu nanoparticles and its application for formic acid oxidation. Int J Hydrogen Energy 2015;40:2182e92. [32] Chen T, Ge C, Zhang Y, Zhao Q, Hao F, Bao N. Bimetallic platinum-bismuth nanoparticles prepared with silsesquioxane for enhanced electrooxidation of formic acid. Int J Hydrogen Energy 2015;40(13):4548e57. [33] Al-Akraa IM, Mohammad AM, El-Deab MS, El-Anadouli BE. Electrocatalysis by design: synergistic catalytic enhancement of formic acid electro-oxidation at coreeshell Pd/Pt nanocatalysts. Int J Hydrogen Energy 2015;40:1789e94.

7

[34] Zhang L-M, Wang Z-B, Zhang J-J, Sui X-L, Zhao L, Gu D-M. Honeycomb-like mesoporous nitrogen-doped carbon supported Pt catalyst for methanol electrooxidation. Carbon 2015;93:1050e8. [35] Kaluza L, Larsen MJ, Zdrazil M, Gulkova D, Vit Z, Solcova O, et al. Highly loaded carbon black supported Pt catalysts for fuel cells. Catal Today 2015;256:375e83. [36] Li M, Wu X, Zeng J, Hou Z, Liao S. Heteroatom doped carbon nanofibers synthesized by chemical vapor deposition as platinum electrocatalyst supports for polymer electrolyte membrane fuel cells. Electrochim Acta 2015;182:351e60. [37] Qian H, Chen S, Fu Y, Wang X. Platinum-palladium bimetallic nanoparticles on graphitic carbon nitride modified carbon black: a highly electroactive and durable catalyst for electrooxidation of alcohols. J Power Sources 2015;300:41e8. [38] Wu S, Liu J, Tian Z, Cai Y, Ye Y, Yuan Q, et al. Highly dispersed ultrafine Pt nanoparticles on reduced graphene oxide nanosheets: in situ sacrificial template synthesis and superior electrocatalytic performance for methanol oxidation. ACS Appl Mater Inter 2015;7:22935e40. [39] Jang HD, Kim SK, Chang H, Choi J-H, Cho B-G, Jo EH, et al. Three-dimensional crumpled graphene-based platinum-gold alloy nanoparticle composites as superior electrocatalysts for direct methanol fuel cells. Carbon 2015;93:869e77. [40] Guo L, Jiang W-J, Zhang Y, Hu J-S, Wei Z-D, Wan L-J. Embedding Pt nanocrystals in n-doped porous carbon/ carbon nanotubes toward highly stable electrocatalysts for the oxygen reduction reaction. ACS Catal 2015;5:2903e9. [41] Chen W, Duan X, Qian G, Chen D, Zhou X. Carbon nanotubes as support in the platinum-catalyzed hydrolytic dehydrogenation of ammonia borane. Chemsuschem 2015;8:2927e31. [42] Wang R-X, Fan Y-J, Wang L, Wu L-N, Sun S-N, Sun S-G. Pt nanocatalysts on a polyindole-functionalized carbon nanotube composite with high performance for methanol electrooxidation. J Power Sources 2015;287:341e8. [43] Xiao M, Zhu J, Ge J, Liu C, Xing W. The enhanced electrocatalytic activity and stability of supported Pt nanopartciles for methanol electro-oxidation through the optimized oxidation degree of carbon nanotubes. J Power Sources 2015;281:34e43. [44] Zhang J-J, Wang Z-B, Li C, Zhao L, Liu J, Zhang L-M, et al. Multiwall-carbon nanotube modified by n-doped carbon quantum dots as Pt catalyst support for methanol electrooxidation. J Power Sources 2015;289:63e70. [45] Yang Z, Nakashima N. A simple preparation of very high methanol tolerant cathode electrocatalyst for direct methanol fuel cell based on polymer-coated carbon nanotube/platinum. Sci Rep 2015;5:12236. [46] Huang XX, Chen Y, Wang XX, Wang JN. Porous-structured platinum nanocrystals supported on a carbon nanotube film with super catalytic activity and durability. J Mater Chem A 2015;3:7862e9. [47] Zhou Y, Yang G, Pan H-B, Zhu C, Fu S, Shi Q, et al. Ultrasonicassisted synthesis of carbon nanotube supported bimetallic Pt-Ru nanoparticles for effective methanol oxidation. J Mater Chem A 2015;3:8459e65. [48] Liu H, Dou M, Wang F, Liu J, Ji J, Li Z. Ordered intermetallic PtFe@Pt core-shell nanoparticles supported on carbon nanotubes with superior activity and durability as oxygen reduction reaction electrocatalysts. RSC Adv 2015;5:66471e5. [49] Xu J, Zhang C, Wang X, Ji H, Zhao C, Wang Y, et al. Fabrication of bi-modal nanoporous bimetallic Pt-Au alloy with excellent electrocatalytic performance towards formic acid oxidation. Green Chem 2011;13:1914e22. [50] Lee D, Jang HY, Hong S, Park S. Synthesis of hollow and nanoporous gold/platinum alloy nanoparticles and their

Please cite this article in press as: Han S-H, et al., Carbon nanotubes supported platinumegold alloy nanocrystals composites with ultrahigh activity for the formic acid oxidation reaction, International Journal of Hydrogen Energy (2016), http://dx.doi.org/10.1016/ j.ijhydene.2016.09.026

8

[51]

[52]

[53]

[54]

[55]

[56]

[57]

[58]

[59]

[60]

[61]

[62]

[63]

i n t e r n a t i o n a l j o u r n a l o f h y d r o g e n e n e r g y x x x ( 2 0 1 6 ) 1 e8

electrocatalytic activity for formic acid oxidation. J Colloid Interf Sci 2012;388:74e9. Rao CV, Cabrera CR, Ishikawa Y. Graphene-supported Pt-Au alloy nanoparticles: a highly efficient anode for direct formic acid fuel cells. J Phys Chem C 2011;115:21963e70. Obradovic MD, Rogan JR, Babic BM, Tripkovic AV, Gautam ARS, Radmilovic VR, et al. Formic acid oxidation on Pt-Au nanoparticles: relation between the catalyst activity and the poisoning rate. J Power Sources 2012;197:72e9. Zhong W, Qi Y, Deng M. The ensemble effect of formic acid oxidation on platinum-gold electrode studied by firstprinciples calculations. J Power Sources 2015;278:203e12. Yao Z, Yue R, Jiang F, Zhai C, Ren F, Du Y. Electrochemicalreduced graphene oxide-modified carbon fiber as Pt-Au nanoparticle support and its high efficient electrocatalytic activity for formic acid oxidation. J Solid State Electr 2013;17:2511e9. Guo C, Zhang M, Tian H, Wang T, Hu J. Preparation and enhanced catalytic activity of Pt-Au alloy catalysts for formic acid oxidation. J Electrochem Soc 2013;160:F1187e91. Zhang Z, Wang Y, Wang X. Nanoporous bimetallic Pt-Au alloy nanocomposites with superior catalytic activity towards electro-oxidation of methanol and formic acid. Nanoscale 2011;3:1663e74. Xie R, Chen M, Wang J, Mei S, Pan Y, Gu H. Facile synthesis of Au-Pt bimetallic nanocomplexes for direct oxidation of methanol and formic acid. RSC Adv 2015;5:650e3. Kim SH, Jeong H, Kim J, Lee IS. Fabrication of supported AuPt alloy nanocrystals with enhanced electrocatalytic activity for formic acid oxidation through conversion chemistry of layer-deposited Pt2þ on Au nanocrystals. Small 2015;11:4884e93. Zheng F, Wong W-T, Yung K-F. Facile design of Au@Pt coreshell nanostructures: formation of Pt submonolayers with tunable coverage and their applications in electrocatalysis. Nano Res 2014;7:410e7. Saipanya S, Srisombat L, Wongtap P, Sarakonsri T. Characterization and formic acid oxidation studies of PtAu nanoparticles. J Nanosci Nanotechno 2014;14:8053e5. Bai Y-C, Zhang W-D, Chen C-H, Zhang J-Q. Carbon nanotubes-supported PtAu-alloy nanoparticles for electrooxidation of formic acid with remarkable activity. J Alloys Compd 2011;509:1029e34. Zheng M, Li P, Fu G, Chen Y, Zhou Y, Tang Y, et al. Efficient anchorage of highly dispersed and ultrafine palladium nanoparticles on the water-soluble phosphonate functionalized multiwall carbon nanotubes. Appl Catal BEnviron 2013;129:394e402. Gong M, Yao Z, Lai F, Chen Y, Tang Y. Platinum-copper alloy nanocrystals supported on reduced graphene oxide: one-pot synthesis and electrocatalytic applications. Carbon 2015;91:338e45.

[64] Fu G, Ding L, Chen Y, Lin J, Tang Y, Lu T. Facile water-based synthesis and catalytic properties of platinum-gold alloy nanocubes. Crystengcomm 2014;16:1606e10. [65] Gao X, Li Y, Zhang Q, Li S, Chen Y, Lee J-M. Polyethyleneimine-assisted synthesis of high-quality platinum/graphene hybrids: the effect of molecular weight on electrochemical properties. J Mater Chem A 2015;3:12000e4. [66] Xu G-R, Liu F-Y, Liu Z-H, Chen Y. Ethanol-tolerant polyethyleneimine functionalized palladium nanowires in alkaline media: the “molecular window gauze” induced the selectivity for the oxygen reduction reaction. J Mater Chem A 2015;3:21083e9. [67] Moulder J, Stickle W, Sobol P, Bomben K. Handbook of X-ray photoelectron spectroscopy. Eden Prairie, MN: Perkin-Elmer Corporation, Physical Electronics Division; 1992. [68] Du C, Chen M, Wang W, Tan Q, Xiong K, Yin G. Platinumbased intermetallic nanotubes with a coreeshell structure as highly active and durable catalysts for fuel cell applications. J Power Sources 2013;240:630e5. [69] Liao M, Xiong J, Fan M, Shi J, Luo C, Zhong C-J, et al. Phase properties of carbon-supported platinum-gold nanoparticles for formic acid eletro-oxidation. J Power Sources 2015;294:201e7. [70] Chen D-J, Zhang Q-L, Feng J-X, Ju K-J, Wang A-J, Wei J, et al. One-pot wet-chemical co-reduction synthesis of bimetallic gold platinum nanochains supported on reduced graphene oxide with enhanced electrocatalytic activity. J Power Sources 2015;287:363e9. [71] Xu H, Ding L-X, Feng J-X, Li G-R. Pt/Ni(OH)2-NiOOH/Pd multiwalled hollow nanorod arrays as superior electrocatalysts for formic acid electrooxidation. Chem Sci 2015;6:6991e8. [72] Xiao M, Li S, Zhu J, Li K, Liu C, Xing W. Highly active PtAu nanowire networks for formic acid oxidation. ChemPlusChem 2014:1123e8. [73] Wang S, Wang X, Jiang SP. Self-assembly of mixed Pt and Au nanoparticles on PDDA-functionalized graphene as effective electrocatalysts for formic acid oxidation of fuel cells. Phys Chem Chem Phys 2011;13:7187e95. [74] Song P, Liu L, Feng J-J, Yuan J, Wang A-J, Xu Q-Q. Poly(ionic liquid) assisted synthesis o f hierarchical gold-platinum alloy nanodendrites with high electrocatalytic properties for ethylene glycol oxidation and oxygen reduction reactions. Int J Hydrogen Energy 2016;41:14058e67. [75] Liu L, Chen L-X, Wang A-J, Yuan J, Shen L, Feng J-J. Hydrogen bubbles template-directed synthesis of self-supported AuPt nanowire networks for improved ethanol oxidation and oxygen reduction reactions. Int J Hydrogen Energy 2016;41:8871e80. [76] Gong M, Fu G, Chen Y, Tang Y, Lu T. Autocatalysis and selective oxidative etching induced synthesis of platinumcopper bimetallic alloy nanodendrites electrocatalysts. ACS Appl Mater Inter 2014;6:7301e8.

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