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Crystallinity-dependence of Ruthenium Nanocatalyst toward Hydrogen Evolution Reaction Yutong Li, Lei A Zhang, Yong Qin, Fuqiang Chu, Yong Kong, Yongxin Tao, Yongxi Li, Yunfei Bu, Dong Ding, and Meilin Liu ACS Catal., Just Accepted Manuscript • DOI: 10.1021/acscatal.8b01609 • Publication Date (Web): 22 May 2018 Downloaded from http://pubs.acs.org on May 22, 2018
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ACS Catalysis
Crystallinity-Dependence of Ruthenium Nanocatalyst toward Hydrogen Evolution Reaction Yutong Li,†, ● Lei A Zhang,‡, ● Yong Qin,*, † Fuqiang Chu,† Yong Kong,† Yongxin Tao,† Yongxi Li,† Yunfei Bu,*, § Dong Ding,‡ and Meilin Liu*, ‡ †
the Jiangsu Key Laboratory of Advanced Materials and Technology, School of Petrochemical Engineering, Changzhou University, Changzhou, Jiangsu, 213164 China
‡
School of Materials Science and Engineering, Georgia Institute of Technology, Atlanta, GA, 30332-2045, United States
§
School of Environmental Science and Engineering, Nanjing University of Information & Technology, Nanjing, Jiangsu, 210044, China
ABSTRACT: The development of highly active and durable inexpensive electrocatalysts for hydrogen evolution reaction (HER) is still a formidable challenge. Herein, an ordered hexagonal-closed-packed (hcp)-Ru nanocrystal coated with a thin layer of N-doped carbon (hcp-Ru@NC) was fabricated through the thermal annealing of polydopamine (PDA)-coated Ru nanoparticle (RuNP@PDA). As an alternative to Pt/C catalyst, the hcp-Ru@NC nanocatalyst exhibited the small overpotential of 27.5 mV at the current density of 10 mA cm-2 as well as long-term stability for HER in acid media. Interestingly, the HER performance of hcp-Ru is highly dependent on its crystallinity. The calculation from density functional theory (DFT) unraveled that the difference in HER activity over various exposed surface causes the crystallinity-independent property of hcp-Ru. The results provided clues to guide the design of Ru-based inexpensive HER electrocatalyst. KEYWORDS: :Ruthenium nanocatalyst, crystallinity-dependence, hydrogen evolution reaction, N-doped graphene, electrocatalyst
INTRODUCTION The environmental deterioration and the forthcoming depletion of traditional fossil resources have triggered a burst of requirements for the development of clean and sustainable energies.1-3 As a renewable and abundant source of fuel on the earth, hydrogen has been considered an ideal clean energy for the replacement of fossil energy in the future.4-6 The production of hydrogen from electrocatalytic water reduction via hydrogen evolution reaction (HER) represents one of the most advanced technologies for sustainable and economic hydrogen production,7-8 but a high voltage is usually required to drive the reaction smoothly, hence it is imperative to develop a highly efficient electrocatalysts for HER which can work at low overpotentials. Currently, Pt is the most effective catalyst, but their prohibitive cost and limited availability are big hurdles for its large-scale application.9-11 Although transitional metals and their derivatives have been largely proposed to replace Pt-based catalysts,12-17 their activity is still far from satisfactory. Ru is a 4d transitional metal, also a member in precious metal family, but its price is ten times lower than that of Pt.18 Ruthenium-based material are the famous electrocatalyst for many classical reactions, such as hydrogen oxidation reaction (HOR),14 methanol oxidation reaction,19 oxy-
gen reduction reaction (ORR),20 and oxygen evolution reaction (OER).21 Theoretically, Ru is also an ideal HER catalyst because it possesses similar hydrogen bond strength (~ 65 kcal mol-1) with Pt,22 unfortunately, it has failed to exhibit comparable HER activity with Pt for a long time.23, 24 As is known, the practical activity of a heterogeneous catalyst is usually strongly affected by its crystal properties such as crystalline phase, degree of crystallinity, and size. For instance, the crystallographic dependence of HER over silver indium sulfide catalyst,25 the sizedependence of CO2 electro-reduction over nanopalladium catalyst,26 and the crystallinity-dependence of OER over Ni-B catalyst,27 have been extensively reported. Among those, a catalyst’s crystallinity is particularly concerned because it usually holds unpredictable effect on its electrocatalytic activity. In some cases, the high crystallinity is favorable for electrocatalysis like HER on tungsten carbide catalyst,28 while in other cases, the poor crystallinity is more favorable like OER on CoWO4 catalyst.29 Recently, Baek30 and Qiao31 group separately found that the composites of Ru nanocrystal with C2N or C3N4 nanosheets showed unprecedented electrocatalytic performance toward HER, which demonstrated the great potentials of Ru-based HER electrocatalyst, however, how does the crystallinity of Ru affect the HER activity still remains unknown.
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Ru nanoparticle (RuNP) fabricated at ambient condition usually adopts the disordered amorphous structure. Thermal annealing at high temperature can enhance its crystallinity.31 To prevent the coalescence during annealing process, a protective coating is commonly suggested. As an emerging protective coating, polydopamine has drawn great concern due to the controllable thickness, abundant N sources, versatile adhesion properties, and excellent carbon yield.32-34 Herein, an hexagonal-closedpacked (hcp)-Ru nanocrystal coated with a thin layer of NC (hcp-Ru@NC) was fabricated through the thermal annealing of polydopamine (PDA)-coated Ru nanoparticle (RuNP@ PDA). The in situ formed NC layer can effectively protect the agglomeration of RuNP during annealing process, which helps to explore the effect of crystallinity on HER activity. It was found for the first time that, the HER performance of hcp-Ru greatly depends on its crystallinity. The fully crystallized hcp-Ru exhibits the best HER performance involving high electrocatalytic activity and super long-term stability in acid media.
RESULTS AND DISCUSSION
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The hcp-Ru@NC was fabricated through a surfactantassisted and PDA-reduced process, as shown in Scheme 1. The Ru precursor, RuCl3·3H2O, was firstly mixed with dopamine (DA) and cetyl trimethyl ammonium bromide (CTAB) in a phosphate buffer solution (PBS, pH=9). The dopamine quickly self-polymerized into polydopamine (PDA), which was then solubilized or dispersed by CTAB at ambient condition. Due to the strong interaction between Ru3+ and –NH2 group,35 Ru3+ was largely absorbed by PDA, and subsequently reduced to RuNP after the mixture was heated to 80 ℃, as evidenced by the TEM (Figure S1a,b), XRD (Figure S1c), and FT-IR (Figure S1d) results. The as-obtained RuNP@PDA was dispersed on a carbon support and annealed at various temperatures for crystallization. The PDA was converted into a layer of NC shell during annealing process. Meanwhile, a threedimensional N-doped graphene (NG) bearing robust 3D structure, hierarchically porous, and abundant N heteroatoms which was proposed in our previous work,36 was selected as the support to load hcp-Ru@NC. The final products were denoted as hcp-Ru@NC-T, here, T represents the annealing temperature.
Scheme 1. Illustration of the fabricating process of hcp-Ru@NC on NG. The crystalline behavior of RuNP@PDA during annealing process was first investigated by powder X-ray diffraction (XRD), as shown in Figure 1. All the materials show a wide peak centred at 26°, which belongs to the C (002) diffraction peak of graphene. Apart from this peak, the RuNP@PDA gives another peak located at 43.8°, which is assigned to the diffraction peak of Ru(101).37 The fairly weak and broad property of Ru(101) reveals the poor crystallinity of the as-prepared RuNP. The RuNP annealed at 400 ℃ (hcp-Ru@NC-400) shows basically identical XRD pattern to that of RuNP@PDA, indicating that RuNP doesn’t crystalize before 400 ℃. At 500 ℃ (hcp-Ru@NC500), the Ru (101) peak turns very significant, and an extra small peak of Ru (100) appears, suggesting that RuNP starts to crystalize at this temperature. Upon the temper–
ature was increased to 600 ℃ (hcp-Ru@NC-600), both Ru (100) and Ru (101) peaks are more and more sharper, and a new peak of Ru (002) emerges, which is indicative of the further improved crystallinity. As the temperature was further increased to 700 ℃ (hcp-Ru@NC-700), these three peaks turn more intense and sharper, and an additional set of Ru (102), Ru (110), Ru (103), Ru (112), and Ru (201) peaks appear. In comparison with the standard XRD card of Ru, it was found that the crystalline phase is assigned to the hcp structure. Additionally, the XRD pattern of hcp-Ru@NC-800 is basically equal with that of hcpRu@NC-700, evidencing that RuNP has been fully crystallized at 700 ℃. Consequently, the degree of crystallinity of RuNP varies with the annealing temperature, which is improved with the increase of temperature below 700 ℃.
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Figure 1. XRD pattern of RuNP@PDA and hcp-Ru@NC annealed at various temperatures ranged from 400 ℃ to 800 ℃.
The morphology of hcp-Ru@NC was further examined by transmission electron microscope (TEM). Figure 2 showed the TEM images of the fully crystallized hcp-Ru@
NC-700 at various resolutions. It can be seen that, the 3D interconnected graphene sheets are thin and transparent, which is favorable to watch RuNP clearly (Figure 2a). RuNP is uniformly anchored on graphene sheets, and the diameter is estimated to be ~4 nm (Figure 2b). hcpRu@NC-700 shows highly crystallized features as indicated by the clear crystal lattice fringes under the observation of high resolution TEM (HRTEM). The spacing of adjacent fringes is mainly 0.21 nm and 0.23 nm (Figure 2b), which is indexed to the (100) and (101) crystalline plane of hcp-Ru@NC, respectively. The NC layer outside hcp-Ru can be clearly observed from the particles at the edge of the graphene sheet. As estimated, the thickness of NC carbon shell is about 0.8 nm (Figure 2c). Additionally, as found from the selected-area electron diffraction (SAED) pattern, hcp-Ru@NC-700 gives clear diffraction spots of (100), (002), (101), (110), and (112) (Figure 2d), also verifying its good crystallinity.
Figure 2. TEM images of hcp-Ru@NC-700 (a, b, c) and the corresponding SAED (d). The inset in (b) is the size distribution curve.
The crystalline process of RuNP was also observed by in situ TEM technique, as shown in Figure S2. It is noteworthy that a crowded area was selected intentionally to avoid the shift of single RuNP at high temperature, (Figure S2a). Also, the range of annealing temperature is extended to 300~900 ℃ for the purpose of watching the evolution process as completely as possible. The crystallinity of Ru was estimated by the number of RuNP with clear lattice fringe. At 300 ℃ (Figure S2b), both the RuNP and the graphene sheet show unclear profile, due to the cover of PDA on their surface. The carbonization of PDA
is firstly observed at 400 ℃ by the clear lattice fringe of carbon (Figure S2c), however, none of the RuNP display clear lattice fringe at this temperature. At 500 ℃, RuNP can be found clearly, and few particles begin to exhibit the clear lattice fringe (Figure S2d). The number of RuNP with clear lattice fringe shows slightly increase at 600 ℃ (Figure S2e), and reaches maximum at 700 ℃ (Figure S2f), whereas has a little degradation at 800 ℃ (Figure S2g) and 900 ℃ (Figure S2h). Clearly, the crystalline behavior of RuNP observed by in situ TEM agrees well with the result from XRD. Apart from the crystalline process,
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the evolution of the size of RuNP can be readily observed as well. The average diameter of the hcp-Ru@NC increases slowly with the temperature rising from 300 ℃ to 700 ℃. In comparison with the changes of RuNP without carbon shell before and after annealing process (Figure S3), it can be found that the outer carbon layer exactly plays critical role in alleviating the coalescence of particles. Upon the temperature further increasing to over 800 ℃, the size of particles increases sharply due most likely that the collapse of NC shell results in the coalescence of neighbored RuNPs.38 The electrocatalytic HER performance of hcp-Ru@NC annealed at various temperatures was evaluated on a glass carbon electrode (GCE) in acidic media (0.5 M H2SO4 solution) by a conventional three-electrode electrochemical cell. All the catalysts have the basically equal Ru loading of ~17 wt.%, as determined by inductively coupled plasma-atomic emission spectrometry (ICP-AES). For comparison, that of the commercial Pt/C (20 wt.%) catalyst was also measured under the same conditions. Their polarization curves and the corresponding Tafel plots of the electrocatalysts were collected in Figure 3a and Figure 3b, respectively. Interestingly, the HER activity of hcpRu@NC varies with the annealing temperature obviously. With the temperature increasing from room temperature to 700 ℃, the HER activity promotes appreciably. Electrochemical active surface area (ECSA) tested by copper underpotential deposition (Cu-upd) method31 verified this trend as well (Figure S4). Turnover frequency (TOF), the best figure-of-merit to evaluate the HER activity of catalysts, was calculated based on the ECSA and the current density from the polarization curves. As expected, the TOF value of the catalysts increases with the annealing temperature from 400 ℃ to 700 ℃ following the LSV, Tafel, and ECSA behavior (Figure 3c), note that the size of the catalysts is slightly increased in this temperature re-
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gion, as revealed by the in situ TEM previously. Generally, smaller size of nanocatalyst is more beneficial to enhance electrocatalytic activity. Nevertheless, hcp-Ru@NC exhibited the abnormally improved electrocatalytic activity with the increased size. Therefore, there exists some other factors to affect the HER activity of hcp-Ru beyond the size. By excluding the effect of the outer NC shell because since PDA has been carbonized at 400 ℃,33 the enhanced HER activity is most likely attributed to the positive contribution of the crystallinity because they really feature very strong interdependency. That is, the HER activity of hcp-Ru mostly depends on its crystallinity. The hcpRu@NC-700 holds the highest degree of crystallinity, hence exhibits the best HER activity. When the annealing temperature achieves to 800 ℃, the effect of the size begins to play the dominant role, which results in the HER degradation of hcp-Ru@NC-800. Additionally, as found from Figure 3a, the overpotential requires to achieve a 10 mA cm-2 cathodic current density (η10) by the hcpRu@NC-700 is as low as 27.5 mV, which is not only much lower than that of the previously reported non-precious metal electrocatalysts,39-41 but also very close to that of the state-of-the-art Pt/C catalyst (22.5 mV) (Figure 3a, b). The Tafel slope of hcp-Ru@NC-700 is as small as 37 mV dec-1, approaching to that of Pt/C (33 mV dec-1) as well. The value of Tafel slope is located between 30 mV dec-1 and 40 mV dec-1, suggesting that HER is performed through the most efficient Volmer-Tafel process.42 At an overpotential of 25 mV, the hcp-Ru@NC-700 exhibits an extremely high TOF of 1.6 s-1, which is much larger than those of the recently reported Ru-based catalyst.30,31 Moreover, hcpRu@NC-700 even displays better HER activity than that of Pt/C (Figure S5) in alkaline media, unfortunately, inferior to some outstanding non-noble metal electrocatalysts reported previously.43
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Figure 3. Polarization curves (a), the corresponding Tafel plots (b), TOF value at the overpotential of 25 mV (c) of the hcpRu@NC catalysts, and the cycle stability tests of the hcp-Ru@NC-700 in 0.5 M H2SO4 (d).
The electrochemical stability of the hcp-Ru@NC was further assessed by an accelerated durability test (ADT) in acidic media. As shown in Figure 3d, after 20,000 cyclic voltammetry (CV) cycles, the polarization curve of hcpRu@NC-700 nearly exhibits negligible shift to achieve the current density of 100 mA cm-2. In striking contrast, that of Pt/C shows significant potential shift of ~23 mV (Figure S6a). By compared with the polarization curve of RuNP and hcp-Ru without NC shell, it can be found that the remarkable stability of hcp-Ru@NC is mostly attributed to the dual effect of NC shell as well as the good crystallinity (Figure S6b,c). The continuous HER performance of hcp-Ru@NC-700 at static overpotential of 27.5 mV (η10) was also performed, shown in Figure S7. Clearly, the current density doesn’t display any decay after a long period of 20,000 s. Both the two long-term tests afford the evidence for the super stability of hcp-Ru@NC-700. In these regards, the highly crystallized hcp-Ru@NC nanocatalyst is an extremely active and durable electrocatalyst for HER in acidic media. It presents comparable activity to the state-of-the-art Pt/C catalyst, but it is more stable as well as at least 10 times cheaper than Pt, which makes it hold great promise for future commercialization. In order to elucidate the intrinsic reason of the crystallinity-dependent property of hcp-Ru toward HER activity, the HER energetics over various exposed surfaces of the hcp-Ru were carried out by density functional theory (DFT). Based on the Tafel slope obtained experimentally, HER catalyzed by the hcp-Ru follows the Volmer-Tafel mechanism, hence the HER activity is evaluated by the three-state diagram consisting of H+ (initial state), H* (intermediate state), and ½ H2 (final state). The Gibbs free energy of adsorption under room temperature and
electric-potential of 1.23 V was derived based on Norskov’s scheme.44 Theoretically, a good catalyst features a moderate free energy for H adsorption (∆G(H*)) as well as desorption. 13, 45 Based on the lattice fringe from the HRTEM and in situ TEM images, Ru slabs with hcp (0001), (10-10), and (10-11) were modeled to represent the dominantly observed surfaces of hcp (002), (100), and (101), respectively. For comparison, the Ru slab with fcc (111) plane representing fcc-Ru was calculated as well. The various Ru slabs with H sitting on their high-symmetry sites were shown in Figure S8, and the corresponding adsorption energy was plotted in Figure S9. It can be seen that various adsorption sites give a strong hydrogen binding, with energy value spanning from ~-0.5 to ~-0.7 eV. From Figure S8, the optimal adsorption site on various surfaces can be readily found (Figure 4a). It is assumed that H is dominantly adsorbed on the surfaces with the most favorable mode to conduct HER. The (∆G(H*) of the typical Ru surfaces was shown in Figure 4b. Clearly, the HER activity of Ru over various surface follows the order of hcp (100) > hcp (002) > hcp (101) > fcc (111), which means that hcp (100) and (002) are the more efficient surfaces than hcp (101) to catalyze HER. Based on this result, the crystallinity-dependent property of hcp-Ru toward HER is readily understandable that the gradually exposed more efficient surface of hcp (100) and (002) with the increase of crystallinity cause the promoted HER activity. Besides, an interest result is that all the surface of hcp-Ru exhibits the better HER activity than fcc-Ru (111), which offers a clue that hcp-Ru may be a better HER electrocatalyst than fcc-Ru. As a result, the choice of the crystalline phase, and the regulation of crystalline surface, should be considered upon designing a Ru-based HER electrocatalyst in the future.
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Figure 4. The most favorable adsorption sites of H on various plane of Ru by DFT calculation, silver gray: Ru; tiny pink: H (a), * and the corresponding (∆G(H ) on fcc (111), hcp (100), hcp (002), and hcp (101) surface, respectively (b).
In summary, hcp-Ru@NC was fabricated through the thermal annealing of RuNP@PDA. The crystallinity of hcp-Ru is gradually enhanced during annealing process with the increase of temperature below 700 ℃. It was found for the first time that, the HER activity of hcp-Ru is highly dependent on its crystallinity. The hcp-Ru@NC prepared at 700 ℃ presented the best HER performance due to its highest degree of crystallinity. As an inexpensive alternative to the Pt/C catalyst, the hcp-Ru@NC-700 exhibited the fairly small overpotential of 27.5 mV at the current density of 10 mA cm-2 and Tafel slope of 34 mV dec-1, extremely high TOF of 1.6 s-1, and super long-term stability in acid media. In combination with the DFT calculation, the crystallinity-dependent property of hcp-Ru toward HER was mostly attributed to the gradually exposed more efficient surface of (100) and 002 during annealing process. The results provided new clues to understand the active site of Ru nanocrystal, which is inspired to develop novel highly efficient and inexpensive HER electrocatalyst.
ASSOCIATED CONTENT AUTHOR INFORMATION
Supporting Information The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acscatal. Experimental section, the characterization of Ru@PDA, the in situ TEM images, the HER performance of catalysts in alkaline media, and the detailed DFT calculation process (PDF)
REFERENCES
Corresponding Author *E-mail:
[email protected]. *E-mail:
[email protected] *E-mail:
[email protected].
ORCID Yong Qin: 0000-0003-4563-8828 Yong Kong: 0000-0003-1270-3232 Yunfei Bu: 0000-0002-1488-5925 Meilin Liu: 0000-0002-6188-2372
Author Contributions ●
The authors are thankful to Prof. Qiaobao Zhang from Xiamen University, China, for their contributions on the in situ TEM observation. The experimental work is financially supported by the Natural Science Foundation of Jiangsu Province, China (BK20161191), the National Natural Science Foundation of China (21476031, 21673024), the Advanced Catalysis and Green Manufacturing Collaborative Innovation Center of Jiangsu Province, and the Jiangsu Key Laboratory of Advanced Materials and Technology (BM2012110). The computational work used Extreme Science and Engineering Discovery Environment (XSEDE), which is supported by the National Science Foundation grant number TG-DMR140083, and National Energy Research Scientific Computing Center (NERSC), a DOE Office of Science User Facility supported by the Office of Science of the U.S. Department of Energy under contract No. DE-AC02-05CH11231.
Y. L. and L. Z. contributed equally to the work.
Notes The authors declare no competing financial interest.
(1) Dovi, V. G.; Friedler, F.; Huisingh, D.; Klemes, J. J. Cleaner Energy for Sustainable Future. J. Clean. Prod. 2009, 17, 889-895. (2) Srirangan, K.; Akawi, L.; Moo-Young, M.; Chou, C. P. Towards Sustainable Production of Clean Energy Carriers from Biomass Resources. Appl. Energy 2012, 100, 172-186. (3) Poizot, P.; Dolhem, F. Clean Energy New Deal for a Sustainable World: from Non-CO2 Generating Energy Sources to Greener Electrochemical Storage Devices. Energ. Environ. Sci. 2011, 4, 2003-2019. (4) Momirlan, M.; Veziroglu, T. N. The Properties of Hydrogen as Fuel Tomorrow in Sustainable Energy System for a Cleaner Planet. Int. J. Hydrogen Energy 2005, 30, 795-802. (5) Dunn, S. Hydrogen Futures: toward a Sustainable Energy System. Int. J. Hydrogen Energy 2002, 27, 235-264. (6) Melis, A.; Happe, T. Hydrogen Production. Green Algae as a Source of Energy. Plant Physiol. 2001, 127, 740-748.
ACKNOWLEDGMENTS
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ACS Catalysis (7) Jiao, Y.; Zheng, Y.; Jaroniec, M. T.; Qiao, S. Z. Design of Electrocatalysts for Oxygen- and Hydrogen-Involving Energy Conversion Reactions. Chem. Soc. Rev. 2015, 44, 2060-2086. (8) Zheng, Y.; Jiao, Y.; Jaroniec, M.; Qiao, S. Z. Advancing the Electrochemistry of the Hydrogen-Evolution Reaction through Combining Experiment and Theory. Angew. Chem. Int. Ed. 2015, 54, 52-65. (9) Tang, C.; Gan, L. F.; Zhang, R.; Lu, W. B.; Jiang, X. E.; Asir, A. M.; Sun, X. P.; Wang, J.; Chen, L. Ternary FexCo1-xP Nanowire Array as a Robust Hydrogen Evolution Reaction Electrocatalyst with Pt-Like Activity: Experimental and Theoretical Insight. Nano Lett. 2016, 16, 6617-6621. (10) Skulason, E.; Karlberg, G. S.; Rossmeisl, J.; Bligaard, T.; Greeley, J.; Jonsson, H.; Norskov, J. K. Density Functional Theory Calculations for the Hydrogen Evolution Reaction in an ElectroChemical Double Layer on the Pt(111) Electrode. Phys. Chem. Chem. Phys. 2007, 9, 3241-3250. (11) Grigoriev, S. A.; Millet, P.; Fateev, V. N. Evaluation of Carbon-Supported Pt and Pd Nanoparticles for the Hydrogen Evolution Reaction in PEM Water Electrolysers. J. Power Sources 2008, 177, 281-285. (12) Jin, H. Y.; Wang, Y.; Su, D. F.; Wei, Z. Z.; Pang, Z. F.; Wang, Y. In situ Cobalt-Cobalt oxide/N-doped Carbon Hybrids as Superior Bifunctional Electrocatalysts for Hydrogen and Oxygen Evolution. J. Am. Chem. Soc. 2015, 137, 2688-2694. (13) Wang, Z. L.; Hao, X. F.; Jiang, Z.; Sun, X. P.; Xu, D.; Wang, J.; Zhong, H. X.; Meng, F. L.; Zhang, X. B. C and N Hybrid Coordination Derived Co-C-N Complex as a Highly Efficient ElectroCatalyst for Hydrogen Evolution Reaction. J. Am. Chem. Soc. 2015, 137, 15070-15073. (14) Huang, Z. F.; Song, J. J.; Li, K.; Muhammad, T.; Wang, Y. T.; Pan, L.; Wang, L.; Zhang, X. W.; Zou, J. J. Hollow Cobalt-Based Bimetallic Sulfide Polyhedral for Efficient All-pH-Value ElectroChemical and Photocatalytic Hydrogen Evolution. J. Am. Chem. Soc. 2016, 138, 1359-1365. (15) Zou, X. X.; Huang, X. X.; Goswami, A.; Silva, R.; Sathe, B. R.; Mikmekova, E.; Asefa, T. Cobalt-Embedded Nitrogen-Rich Carbon Nanotubes Efficiently Catalyze Hydrogen Evolution Reaction at All pH Values. Angew. Chem. Int. Edit. 2014, 53, 43724376. (16) Li, F.; Bu, Y.F.; Lü, Z.J.; Mahmood, J.; Han, G.F.; Ahmad, I.; Kim, G.; Zhong, Q.; Baek, J.B. Porous Cobalt Phosphide Polyhedrons with Iron Doping as an Efficient Bifunctional Electrocatalyst. Small, 2017, 13, 1701167. (17) Li, F.; Zhao, X.L.; Mahmood, J.; Okyay, M.S.; Jung, S.M.; Ahmad, I.; Kim, S.J.; Han, G.F.; Park, N. J.; Baek, J.B. Macroporous Inverse Opal-like MoxC with Incorporated Mo Vacancies for Significantly Enhanced Hydrogen Evolution. ACS Nano, 2017, 11, 7527-7533. (18) Over, H. Surface Chemistry of Ruthenium Dioxide in Heterogeneous Catalysis and Electrocatalysis: From Fundamental to Applied Research. Chem. Rev. 2012, 112, 3356-3426. (19) Ohyama, J.; Kumada, D.; Satsuma, A. Improved Hydrogen Oxidation Reaction under Alkaline Conditions by Rutheniumiridium Alloyed Nanoparticles. J. Mater. Chem. A 2016, 4, 1598015985. (20) Zhang, C. H.; Sha, J. W.; Fei, H. L.; Liu, M. J.; Yazdi, S.; Zhang, J. B.; Zhong, Q. F.; Zou, X. L.; Zhao, N. Q.; Yu, H. S.; Jiang, Z.; Ringe, E.; Yakobson, B. I.; Dong, J. C.; Chen, D. L.; Tour, J. M. Single-Atomic Ruthenium Catalytic Sites on Nitrogen-Doped Graphene for Oxygen Reduction Reaction in Acidic Medium. ACS Nano 2017, 11, 6930-6941. (21) Kibsgaard, J.; Hellstern, T. R.; Choi, S. J.; Reinecke, B. N.; Jaramillo, T. F. Mesoporous Ruthenium/Ruthenium Oxide Thin
Films: Active Electrocatalysts for the Oxygen Evolution Reaction. ChemElectroChem 2017, 4, 2480-2485. (22) Mitchell, W. J.; Xie, J.; Jachimowski, T. A.; Weinberg, W. H. Carbon Monoxide Hydrogenation on the Ru(001) Surface at Low Temperature Using Gas-Phase Atomic Hydrogen: Spectroscopic Evidence for the Carbonyl Insertion Mechanism on a Transition Metal Surface. J. Am. Chem. Soc. 1995, 117, 2606-2617. (23) Chen, Z.; Lu, J. F.; Ai, Y. J.; Ji, Y. F.; Adschiri, T.; Wan, L. J. Ruthenium/Graphene-Like Layered Carbon Composite as an Efficient Hydrogen Evolution Reaction Electrocatalyst. ACS Appl. Mater. Inter. 2016, 8, 35132-35137. (24) Drouet, S.; Creus, J.; Colliere, V.; Amiens, C.; García-Antón, C.; Sala, X.; Philippot, K. A Porous Ru Nanomaterial as an Efficient Electrocatalyst for the Hydrogen Evolution Reaction under Acidic and Neutral Conditions. Chem. Commun. 2017, 53, 1171311716. (25) Saji, P.; Ganguli, A. K.; Bhat, M. A.; Ingole, P. P. Probing the Crystal Structure, Composition-Dependent Absolute Energy Levels, and Electrocatalytic Properties of Silver Indium Sulfide Nanostructures. ChemPhysChem 2016, 17, 1195-1203. (26) Rahaman, M.; Dutta, A.; Broekmann, P. Size-Dependent Activity of Palladium Nanoparticles: Efficient Conversion of CO2 into Formate at Low Overpotentials. ChemSusChem 2017, 10, 1733-1741. (27) Jiang, W. J.; Niu, S.; Tang, T.; Zhang, Q. H.; Liu, X. Z.; Zhang, Y.; Chen, Y. Y.; Li, J. H.; Gu, L.; Wan, L. J.; Hu, J. S. V. Crystallinity-Modulated Electrocatalytic Activity of a Nickel(II) Borate Thin Layer on Ni3B for Efficient Water Oxidation. Angew. Chem. Int. Edit. 2017, 56, 6572-6577. (28) Fan, X. J.; Zhou, H. Q.; Guo, X. WC Nanocrystals Grown on Vertically Aligned Carbon Nanotubes: An Efficient and Stable Electrocatalyst for Hydrogen Evolution Reaction. ACS Nano 2015, 9, 5125-5134. (29) Tian, T.; Jiang, J.; Ai, L. H. In situ Electrochemically Generated Composite-Type CoOx/WOx in Self-Activated Cobalt Tungstate Nanostructures: Implication for Highly Enhanced Electrocatalytic Oxygen Evolution. Electrochim. Acta 2017, 224, 551-560. (30) Mahmood, J.; Li, F.; Jung, S. M.; Okyay, M. S.; Ahmad, I.; Kim, S. J.; Park, N.; Jeong, H. Y.; Baek, J. B. An Efficient and pHUniversal Ruthenium-Based Catalyst for the Hydrogen Evolution Reaction. Nat. Nanotechnol. 2017, 12, 441-446. (31) Zheng, Y.; Jiao, Y.; Zhu, Y. H.; Li, L. H.; Han, Y.; Chen, Y.; Jaroniec, M.; Qiao, S. Z. High Electrocatalytic Hydrogen Evolution Activity of an Anomalous Ruthenium Catalyst. J. Am. Chem. Soc. 2016, 138, 16174-16181. (32) Chung, D. Y.; Jun, S. W.; Yoon, G.; Kwon, S. G.; Shin, D. Y.; Seo, P.; Yoo, J. M.; Shin, H.; Chung, Y. H.; Kim, H.; Mun, B. S.; Lee, K. S.; Lee, N. S.; Yoo, S. J.; Lim, D. H.; Kang, K.; Sung, Y. E.; Hyeon, T. Highly Durable and Active PtFe Nanocatalyst for Electrochemical Oxygen Reduction Reaction. J. Am. Chem. Soc. 2015, 137, 15478-15485. (33) Wang, P.; Zhang, G.; Cheng, J.; You, Y.; Li, Y. K.; Ding, C.; Gu, J. J.; Zheng, X. S.; Zhang, C. F.; Cao, F. F. Facile Synthesis of Carbon-Coated Spinel Li4Ti5O12/Rutile-TiO2 Composites as an Improved Anode Material in Full Lithium-Ion Batteries with LiFePO4@N-Doped Carbon Cathode. ACS Appl. Mater. Inter. 2017, 9, 6138-6143. (34) Liang, J.; Xiao, C. H.; Chen, X.; Gao, R. X.; Ding, S. J. Porous Gamma-Fe2O3 Spheres Coated with N-doped Carbon from PolyDopamine as Li-ion Battery Anode Materials. Nanotechnology 2016, 27, 215403. (35) Ji, S. F.; Chen, Y. J.; Fu, Q.; Chen, Y. F.;Dong, J. C.; Chen, W. X.; Li, Z.; Wang, Y.; Gu, L.; He, W.; Chen, C.; Peng, Q.; Huang, Y.; Duan, X. F.; Wang, D. S.; Draxl, C.; Li, Y. D. Confined Pyrolysis
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within Metal-Organic Frameworks To Form Uniform Ru3 Clusters for Efficient Oxidation of Alcohols. J. Am. Chem. Soc. 2017, 139, 9795−9798. (36) Qin, Y.; Yuan, J.; Li, J.; Chen, D. C.; Kong, Y.; Chu, F. Q.; Tao, Y. X.; Liu, M. L. Crosslinking Graphene Oxide into Robust 3D Porous N-Doped Graphene. Adv. Mater. 2015, 27, 5171–5175. (37) Tee, S. Y.; Lee, C. J. J.; Dinachali, S. S.; Lai S. C.; Williams, E. L.; Luo, H. K.; Chi, D. Z.; Hor, T. S. A.; Han, M. Y. Amorphous Ruthenium Nanoparticles for Enhanced Electrochemical Water Splitting. Nanotechnology 2015, 26, 415401. (38) Fischer, A.; Antonietti, M.; Thomas, A. Growth Confined by the Nitrogen Source: Synthesis of Pure Metal Nitride Nanoparticles in Mesoporous Graphitic Carbon Nitride. Adv. Mater. 2007, 19, 264-267. (39)Laursen, A. B.; Patraju, K. R.; Whitaker, M. J.; Retuerto, M.; Sarkar, T.; Yao, N.; Ramanujachary, K. V.; Greenblatt, M.; Dismukes, G. C. Nanocrystalline Ni5P4: a Hydrogen Evolution Electrocatalyst of Exceptional Efficiency in Both Alkaline and Acidic Media. Energ. Environ. Sci. 2015, 8, 1027-1034. (40)Fei, H. L.; Dong, J. C.; Arellano-Jimenez, M. J.; Ye, G. L.; Kim, N. D.; Samuel, E. L. G.; Peng, Z. W.; Zhu, Z.; Qin, F.; Bao, J. M., Yacaman, M. J.; Ajayan, P. M.; Chen, D. L.; Tour, J. M. Atomic Cobalt on Nitrogen-Doped Graphene for Hydrogen Generation. Nat. Commun. 2015, 6, 8668. (41) Ito, Y.; Cong, W. T.; Fujita, T.; Tang, Z.; Chen, M. W. High Catalytic Activity of Nitrogen and Sulfur Co-Doped Nanoporous Graphene in the Hydrogen Evolution Reaction. Angew. Chem. Int. Ed. 2015, 54, 2131-2136. (42) Xiao, P.; Chen, W.; Wang, X. A Review of Phosphide-Based Materials for Electrocatalytic Hydrogen Evolution. Adv. Energy Mater. 2015, 5, 1500985. (43) Xiao, P.; Sk, M. A.; Thia, L.; Ge, X. M.; Lim, R. J.; Wang, J. Y.; Lima, K. H.; Wang, X. Molybdenum Phosphide as an Efficient Electrocatalyst for the Hydrogen Evolution Reaction. Energ. Environ. Sci. 2014, 7, 2624-2629. (44) Norskov, J. K.; Rossmeisl, J.; Logadottir, A.; Lindqvist, L. L.; Kitchin, J. R.; Bligaard, T.; Jónsson, H. J. Origin of the Overpotential for Oxygen Reduction at a Fuel-Cell Cathode. Phys. Chem. B 2004, 108, 17886-17892. (45)Wang, S. M.; Zhang, L.; Qin, Y.; Ding, D.; Bu, Y. F.; Chu, F. Q.; Kong, Y.; Liu, M. L. Co,N-Codoped Graphene as Efficient Electrocatalyst for Hydrogen Evolution Reaction: Insight into the Active Centre. J. Power Sources 2017, 363, 260-268.
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