An Earth-Abundant Tungsten–Nickel Alloy Electrocatalyst for Superior

Feb 21, 2018 - However, if the annealing temperature is too high, the separated metallic tungsten domain would be formed and the surface morphology co...
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An Earth-abundant Tungsten-Nickel Alloy Electrocatalyst for Superior Hydrogen Evolution Jean Marie Vianney Nsanzimana, Yuecheng Peng, Mao Miao, Reddu Vikas, Wenyu Zhang, Hongming Wang, Bao Yu Xia, and Xin Wang ACS Appl. Nano Mater., Just Accepted Manuscript • DOI: 10.1021/acsanm.7b00383 • Publication Date (Web): 21 Feb 2018 Downloaded from http://pubs.acs.org on February 23, 2018

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An Earth-abundant Tungsten-Nickel Alloy Electrocatalyst for Superior Hydrogen Evolution Jean Marie Vianney Nsanzimana,† Yeucheng Peng,† Mao Miao,‡ Vikas Reddu,† Wenyu Zhang,† Hongming Wang,# Bao Yu Xia,‡* and Xin Wang†* †

School of Chemical and Biomedical Engineering, Nanyang Technological University, 50 Nanyang Avenue, Singapore 639798, Singapore E-mail: [email protected]

Key Laboratory of Material Chemistry for Energy Conversion and Storage (Ministry of Education), Hubei Key Laboratory of Material Chemistry and Service Failure, School of Chemistry and Chemical Engineering, Wuhan National Laboratory for Optoelectronics, Wuhan National Laboratory for Optoelectronics, Huazhong University of Science and Technology (HUST), 1037 Luoyu Road, Wuhan, 430074, China E-mail: [email protected] # School of Chemistry and Institute for Advanced Study, Nanchang University, 999 Xuefu Road, Nanchang, PR China ABSTRACT: Hydrogen production with high purity through water splitting has been proved to be a potential energy technology but requires highly efficient, low cost and robust electrocatalysts. Herein, a tungsten-nickel/nickel foam hybrid is prepared by a facile method and exhibits an outstanding hydrogen evolution reaction activity and remarkable stability in alkaline solution. It only requires an overpotential of 36 mV to afford the current density of 10 mA cm-2 with a small Tafel slope of 43 mV dec-1. Owing to the excellent electrocatalytic performance arising from the synergistic effect of binary tungsten-nickel interacting through the d-orbital electron transfer, the as-prepared material is the best among tungsten-based HER electrocatalyst. The lower adsorption energy of water molecules and a small Gibbs free energy of hydrogen adsorption (0.17 eV) on tungsten atoms of WNi (111) from DFT calculations reveal the favorable water electrolysis kinetics. Moreover, the simple preparation strategy can be extended to design of other active materials for clean energy technology applications and beyond.

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KEYWORDS: WNi alloy, electrocatalyst, electronic effect, hydrogen evolution reaction, water splitting, DFT Calculation

INTRODUCTION The world energy consumption is mainly based on hydrocarbon fuels which is depleting, and the related carbon dioxide emission contributes greatly to global warming. Alternative clean energy sources are thus required for the development of sustainable environment and society.(1-2) As a promising carbon-neutral fuel alternative, hydrogen energy has gained great interest over the past decades and clean and sustainable production of hydrogen is crucial for future hydrogen energy technologies.(3-5) Among various approaches, electrochemical water splitting has gained a lot of interest due to its production of high purity hydrogen and high process flexibility. But large scale application of this technology needs efficient and costeffective electrocatalysts.(6-7) Over the past decades, tremendous efforts have been devoted to exploring highly effective and durable earth-abundant electrocatalysts to replace precious metal-based catalysts for alkaline water electrolysis. Competitive materials such as chalcogenides,(8) phosphides,(9) nitrides,(10-11) carbides,(12-13) borides,(14-15) metal alloys,(16) and metal-free catalysts have been reported.(7,17) Nickel-based alloys are among the most promising catalysts because of their low cost and tunable electrocatalytic properties via the synergistic nearby elements.(18-19) Compared to their parent metals, nickel-based bimetallic system reduces the water molecular adsorption energy and hence, small Gibbs free energy of hydrogen adsorption which results into advanced HER electroactivity.(20-21) Here we present a novel tungsten-nickel alloy/Ni foam (NF) hybrid annealed at 450 oC (denoted as WNi/NF450) with an extraordinary HER performance in 1.0 M KOH electrolyte. The sample electrode exhibits a low overpotential of 36 mV at 10 mA cm-2 and a small Tafel slope of 43 mV dec-1. The excellent performance can be ascribed to the synergistic effect of 2 ACS Paragon Plus Environment

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binary tungsten-nickel alloy interacting through the transfer of d-orbital electrons. This work presents a simple and facile approach to produce highly efficient and durable electrocatalyst towards HER in alkaline electrolyte. RESULTS AND DISCUSSION The three-dimensional (3D) tungsten-nickel alloy is formed by the hydrothermal treatment of Ni foam (NF) with ammonium metatungstate hydrate, followed annealing at 450 oC in the hydrogen environment (see the Experimental Section for details, the obtained sample is denoted WNi/NF450). The formation of WNi alloy follows the Ni-W phase diagram.(22) Herein, ammonium based tungsten is used as tungsten source, while the NF acts as not only the nickel source but also the substrate for growing WNi alloys. The fabrication of WNi alloy electrode based on the present method is depicted in Figure 1. The NF appears overt green after hydrothermal treatment and turns black after annealing in the presence of pure H2 gas (Figure S1). The as-obtained alloy hybrid is examined by field-emission scanning electron microscopy (FE-SEM). After hydrothermal treatment, many microparticles in rhombic dodecahedron shape with the size of ~ 2 µm are uniformly distributed on the surface of NF (Figure 2a). With a closer observation by FE-SEM (Figure S2), these microparticles are almost tightly bound to the NF (inset Figure 2a). After annealing at 450 oC in the presence of H2, some microcracks appear around these microparticles (Figure 2b and inset). The annealing process also serves the purpose of removing residual oxyhydrogen species generated in the previous hydrothermal process. The tungsten precursors play important role in the consequent formation of WNi alloy. With addition of too much tungsten precursors, enormous flakes and particles appear on the NF substrate (Figure S3). Thus, the concentration of tungsten source should be controlled to ensure the successful formation of alloys firmly anchored on the NF substrate. More information is obtained by high-resolution TEM (HRTEM). The High-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM) image of a portion of WNi particle after annealing at 450 oC reveals the 3 ACS Paragon Plus Environment

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homogeneous distribution of both Ni and W elements (Figure 2c). The lattice fringes in Figure 2d with a spacing of ~ 0.20 nm correspond to predominant (111) crystal plane and indicate the formation of WNi alloy. The distinct diffraction spots in the inset of Figure 2d confirm the single crystallinity nature of WNi alloy particles in the as-prepared WNi/NF450 hybrid. X-ray powder diffraction (XRD) analysis in Figure 3a also verifies the crystalline nature of as-synthesized materials. For the hydrothermal products dried at 80 oC, besides the prominent Ni peaks (PDF No. 04-0850), small shoulder peaks at 23.3o, 28.4o, and 37.3o are indexed to (020), (112), and (202) of WO3 species (JCPDS card no: 71-0131), respectively, which are from metal (hydro)oxides formed during the hydrothermal process (Figure S4a). When the material was annealed at 300 oC (Figure S4a), only a slightly change occurred where the peak at 23.3o disappeared and was replaced by a new peak at 23.8o ascribed to (010) of WO2.83.(23) After annealing at 450 oC in hydrogen environment, the sample (WNi/NF450) peeled off from the NF substrate exhibits peaks at 36o, 39o, 43o, 48o and 54o, which are indexed to (040), (140), (042), (213), and (322) of WNi alloy (JCPDS card no: 00-047-1172), respectively, while the peak assigned to oxygen-deficient tungsten oxide (WO3-x) at 23.8o is still observed. With a higher annealing temperature of 600 oC, new emerged peaks at ~ 40.3o, 58.3o and 73o are ascribed to (110), (200) and (211) of the metallic tungsten phase (PDF No. 04-0806), respectively (Figure S4b). The atomic elemental composition is analyzed by energy-dispersive spectroscopy (EDS) and the results show an atomic W:Ni ratio of approximately 1:1 in the WNi alloy supported on NF (Figure S5 and Table S1). Furthermore, this agrees with the homogeneous distribution of both Ni and W elements observed in HAADF-STEM image (Figure 2c). The surface state of the as-prepared WNi alloys is further examined by X-ray photoelectron spectroscopy (XPS). The XPS results reveal the absence of tungsten in the pretreated bare NFs (Figure S6) and the presence of both nickel and tungsten (Figure 3b) with an atomic ratio close to EDS 4 ACS Paragon Plus Environment

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analysis (Table S1).(24) The Ni 2p3/2 peak at 855.3 eV is present both in WNi alloys supported on NF and bare NF (Figure 3c). Moreover, a new peak ascribed to metallic Ni (Ni(0)) at 851.8 eV is observed only in WNi/NF450 in agreement with Ni59W41 alloy in the literature (25), showing that it is from WNi alloy instead of nickel foam, as this state is not present in the pretreated bare NF.(26-27) Figure 3d shows two major peaks about 2.3 eV away from each other with a ratio of around 4:3 at 35.5 and 37.8 eV corresponding to 4f7/2 and 5p5/2 states of W with a higher oxidation state (W6+) in the WNi/NF450, respectively. A minor peak for W5p3/2 appears about 5.5 eV from W4f7/2 which indicates the presence of tungsten in metallic state.(26,28-29) The annealing treatment of tungsten oxide in the presence of H2 at moderate temperature undergo partially reduction by creating oxygen vacancies.(30) Moreover, a peak at 33.4 eV for W 4f7/2 state can be attributed to the formation of metallic tungsten (W(0)) in the as-prepared material and it experiences a chemical shift due to the electron transfer with nickel.(28,31) Furthermore, the O 1s spectrum of the pretreated bare NF and WNi/NF450 electrode shows that the predominant amount in the latter is surface lattice oxygen at 530.4 eV, while it is from surface adsorbed oxygen species at 529.4 eV for the former (Figure S6c).(32) This further agrees with the XRD and EDS results about the oxygen presence, showing the partial reduction of the as-prepared electrode at these conditions.(33) The electrocatalytic hydrogen evolution properties of the as-prepared WNi/NF hybrid are studied in H2 saturated 1.0 M KOH solution at room temperature. The pretreated bare NF and commercial Pt/C catalysts (50%, GasHub Technology) with the same mass loading are also prepared and studied for comparison.(34) The polarization curve of annealed WNi/NF450 shows an outstanding HER electrochemical activity with a small onset overpotential of 2 mV and then the current density rises rapidly at larger overpotentials (Figure 4a).(35) The WNi/NF450 catalyst affords a geometric current density (jgeo) of 10 mA cm-2 at an overpotential of 36 mV, which is similar to Pt based catalyst. In comparison, the bare NF shows insignificant HER activity and depicts a high overpotential of up to 314 mV to deliver 5 ACS Paragon Plus Environment

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10 mA cm-2. Thus, the electrocatalytic activity of this hybrid material is attributed not only to the catalyst but also to the substrate which is one of the advantages for most self-supported electroactive materials. The lower overpotential for the as-prepared hybrid electrode arises from the catalyst assisted by a highly conductive substrate. Moreover, at higher overpotentials, WNi/NF450 catalyst outperforms Pt/C catalyst in the cathodic current density. For example, to achieve a current density of 30 and 50 mA cm-2, the overpotentials are only 64 and 78 mV for WNi/NF450 but 94 mV and 150 mV for commercial Pt/C catalysts, respectively. This could be attributed not only to the synergistic effect in binary metal catalyst, but also to the improved contact between the catalyst and the substrate while in Pt/C this effect is limited by binder usage and poor contact between catalyst and the substrate. WNi/NF450 also displays a superior activity compared to some other nickel-based HER catalysts (Table S2). To name a few, based on the overpotentials required to deliver a current density of 10 mA cm-2,(7) this material requires less overpotential (36 mV) than other excellent HER catalysts prepared on NF such as NiSe (96 mV),(24) Ni2P/Ni/NF (98 mV),(36) HP-NiSe2 (57 mV, in acidic medium),(37) V/NF (176 mV),(34) WS2(1-x)Se2x/NiSe2 (88 mV, in acidic medium),(38) Mo6Ni6C grown on nickel foam (51 mV, in acidic medium).(38) Additionally, it is even better than the amorphous tungsten-doped nickel phosphide (aWNP)/NF which exhibited an onset potential of 50 mV, overpotential of 110 mV at 20 mA cm−2, and small Tafel slope of 39 mV dec−1 in acidic medium and at 160 mV in alkaline solution.(29) Figure 4b shows a lower Tafel slope of 43 mV dec-1 for WNi/NF450 catalyst, which is similar to Pt/C (41 mV dec-1) and much smaller than NF (136 mV dec-1).(24) This reveals a favorable HER kinetics of WNi/NF450 electrode.(39-40) Fundamentally, the HER process in alkaline electrolyte proceeds with the following two or three steps: Volmer reaction (electrochemical hydrogen adsorption: H2O + M + e → MHads + OH−, 120 mV dec-1), followed by Heyrovsky reaction (electrochemical desorption: MHads + H2O + e → M + OH− + H2, 40 mV dec-1) and/or Tafel reaction (chemical desorption: 2MHads →2M + H2, 30 mV dec-1).(41) The Tafel 6 ACS Paragon Plus Environment

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slope of the as-prepared WNi/NF450 catalyst (43 mV dec-1) is very close to 41 mV dec-1 for Pt/C at the same condition (Figure 4b). This implies the similar mechanism following VolmerHeyrovsky mechanism while the Heyrovsky step acts as the rate-limiting step for both Pt/C and WNi/NF450 hybrid catalysts in alkaline solution.(42) The optimization of the as-prepared catalyst is also studied by tuning the annealing temperatures in the presence of pure H2 gas. The as-prepared electrode dried at 80 oC prior to the annealing process (denoted as WNi/NF80), exhibits a poor performance compared to the samples annealed at 300 oC, 450 oC, and 600 oC (denoted as WNi/NF300, WNi/NF450, and WNi/NF600, respectively) (Figure 4c). By annealing at 300 oC, a slightly enhanced catalytic performance is observed for WNi/NF300, which may be mainly due to the insufficient removal of metal (hydro)oxides and hence insufficient alloying of tungsten and nickel. The WNi/NF450 catalyst outperforms the rest (Figure 4d and Figure S7). Therefore, a high annealing temperature is needed to ensure sufficient reduction of metal oxide and formation of alloy. However, if the annealing temperature is too high, the separated metallic tungsten domain would be formed and the surface morphology could be destroyed and thus result in a reduced electrocatalytic performance.(34,43) Though the optimized electrode contains partially reduced tungsten oxides, partially reduced tungsten oxide had been reported to activate molecular H2 and exhibits high conductivity compared to inert tungsten oxide, and hence, with highly conductive substrate its presence does not severely limit the electrode activity.(30,44) Furthermore, it had been reported that the presence of native oxidized species including tungsten oxide in nickel tungsten alloy based material protects the catalyst against corrosion.(33) Moreover, WNi/NF450 electrode also exhibits an enhanced catalytic activity towards oxygen evolution and thus could be used as a bifunctional electrocatalyst in the overall water splitting technology (Figure S8). Additionally, the optimized electrode was also

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electroactive in acidic electrolyte. In 0.5 M H2SO4, an overpotential of 100 mV is required to afford a current density of 10 mA cm-2 (Figure S9a). Electrochemical stability is another crucial criterion for earth-abundant catalyst to compete with the scarce and precious Pt-based catalysts. Figure 5a shows no significant potential loss to afford a constant high current density of 20 mA cm-2 for 12 hours. Furthermore, the polarization curves before and after continuous 1000 cycles are compared and almost overlap (Figure 5b). Both observations from the durability tests indicate that the as-prepared catalyst can stably survive in the harsh electrolyte solution. SEM and XPS analysis of WNi/NF450 after HER testing also indicate the similar surface structure, valence state and the consistent constituents (Figure S10). Additionally, electrochemical impedance spectroscopy (Figure S11 a) reavels no significant changes in the series resistance (Rs), constant phase element (CPE), and charge transfer resistance (Rct) after the stability test. The Rs barely changed (2.23 vs 2.24 Ω), while the Rct reduced from 19.09 to 16.85 Ω. The high stability can be attributed to the

thermodynamics associated with Lewis acid-base interaction of intermetallic phases, where the stabilities of the alloy are enhanced by hypo-hyper-d-intermetallic bonding.(45) Furthermore, the stability was also investigated by both 1000 continuous cycles and by collecting a chronopotentiometric curve in 0.5 M H2SO4 electrolyte (Figure S9). Overall, it shows promising stability in the tested time period which agrees with the literature that the presence of tungsten oxide would enhance the corrosion resistance.(29) The excellent electrocatalytic activity can be attributed to the synergistic properties of homogeneously reduced tungsten-nickel alloy and high electrochemically active surface area (ECSA) upon annealing.(46-47) Firstly, an electrochemical double-layer capacitance (Cdl) is found at 0.13 mF cm-2 at 1.15 V, which is almost three times than tungsten-nickel supported on NF without annealing (0.04 mF cm-2, Figure S12). This Cdl which correlates with ESCA was derived from CV curves collected in a potential window where no Faradaic process 8 ACS Paragon Plus Environment

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occurred. The larger Cdl indicates more surface reactive sites of annealed samples are exposed to reaction media. These results are consistent with the rough surface observed on the tungsten-nickel particles after annealing (Figure 2b). Furthermore, the WNi/NF450 catalyst shows a smaller charge transfer resistance compared to NF substrate (Figure S11b), which can be attributed to the binary metal system. Though the NF substrate is agreed upon as a highly conductive substrate, the reduced charge transfer resistance for the hybrid electrode shows that the catalyst alloyed onto the substrate is crucial for the outstanding performance. In this case, alloying W with Ni results in d-electron density modification and hence advanced intrinsic electrocatalytic activity.(19) Furthermore, a best catalyst for HER should have a Gibbs free energy for hydrogen adsorption close to zero.(48-49) The favorable kinetics and enhanced HER electrocatalytic activity of the as-prepared WNi/NF hybrid electrocatalysts can be explained by the modification of electron density in d-orbitals to tune the H-binding energies and optimize Gibbs free energy upon nickel-tungsten alloying.(48) DFT calculations are carried out to better understand the water electrolysis mechanism for HER process. It has been reported that the hydrogen chemisorption energies reflects the kinetics for hydrogen-evolving catalyst.(49) Figure 5c shows the reaction pathways for O-H bond cleavage of water molecule at W and Ni sites on the WNi (111) surfaces. The adsorption energy of H2O at W sites is larger than that at Ni sites, which means that H2O is more favorably adsorbed at W sites. The energy barriers for water dissociation are found to be 0.56 and 0.75 eV for W sites and Ni sites on (111) surfaces of WNi alloys. It suggests that W sites on WNi (111) surfaces are more reactive for O-H bond cleavage in comparison to Ni sites, which makes W sites more suitable for water splitting reaction. In Figure 5d, it is found that the free energy of hydrogen evolution on WNi (111) is much lower than that of Ni (111), indicating that WNi alloy is much more active than Ni catalyst, which is in well agreement with our experimental results. Moreover, W centers demonstrate a lower ∆G (0.17 eV) than 9 ACS Paragon Plus Environment

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Ni centers (0.32 eV) on the WNi (111) surface. This reveals W centers hold a higher catalyzing activity than Ni centers and are the main active sites in WNi catalysts. CONCLUSION In summary, 3D tungsten-nickel/nickel foam hybrid is successfully prepared by a facile hydrothermal approach followed by annealing treatment in the presence of hydrogen. The asprepared WNi/NF450 exhibits an extraordinary hydrogen evolution activity towards alkaline water splitting. It only requires an overpotential of 36 mV to afford the current density of 10 mA cm-2 with a small onset potential of 2 mV and Tafel slope of 43 mV dec-1, which is comparable to commercial precious Pt catalyst. The excellent electrocatalytic performance arises from the synergistic effect of binary tungsten-nickel interacting through the electron transfer of d-orbital electrons and the assistance of NF substrate. The DFT calculation results reveal that the lower hydrogen chemisorption energies and reduced Gibbs free energy on the surface of the tungsten-nickel/NF hybrid electrode promote water electrolysis process..

EXPERIMENTAL SECTION Materials Synthesis. All chemicals used in this study were used as received. The tungstennickel particles/nickel foam (NF) hybrid was prepared by a simple hydrothermal technique. Firstly, the NFs were treated with 3 M HCl solution for 10 minutes to ensure the surface of NFs were well cleaned before use. After acid cleaning, they were washed with deionized water (DI-water) several times to ensure the pH value reaches a neutral condition. Secondly, 0.25 M solution of ammonium metatungstate hydrate ((NH4)6H2W12O40 ● xH2O, SigmaAldrich, CAS: 12333-11-8) was prepared in 15 mL of ultra-purified water from a Milli-Q Plus system (Millipore, >18.2 MΩ.cm) and stirred at room temperature for 30 minutes. One pretreated bare NF (1 x 3 cm2)(24,50-51) was submerged into the High Pressure Polytetrafluoroethylene (PTFE) Lined Vessel of 50 mL containing the precursor solution and ultrasonicated for 5 minutes prior to the hydrothermal procedure. Afterwards, it was placed 10 ACS Paragon Plus Environment

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and sealed in the Teflon lined hydrothermal synthesis reactor and then placed in an electric oven. The temperature was raised at a maximum of 170 oC and maintained for 20 hours. After this period, it was cooled down at room temperature. Then the modified NF was taken out and washed subsequently with DI-water and ethanol, respectively. The NF was placed on cleaned and dried porcelain crucible and transferred in a tube reactor. Pure H2 gas was flushed for 30 minutes to provide an air-free H2 gas saturated atmosphere. The temperature was raised slowly until it reached reaction temperature (such as 450 oC) with a heating speed of 2 oC min1

and was maintained for an hour in the presence of H2 gas flow. The final binary tungsten-

nickel/NF electrode was stable in the air after annealing. The color of the as-fabricated electrode after annealing in H2 gas was black. Characterizations. The field emission scanning electron microscopy (FESEM, JEOL JSM 6700F) was used to study the surface material morphology which was also equipped with energy-dispersive spectroscopy (EDS, INCA PentaFET-x3) and it was used to analyse the material composition. To further examine the as-prepared material, the high-resolution transmission electron microscopy (HRTEM) image, SAED, elemental mapping and the Highangle annular dark-field scanning transmission electron microscopy (HAADF-STEM) were performed by TEM (JEOEL JEM 2100, 200 kV). Powder X-ray diffraction (XRD) patterns were collected by using a Bruker diffractometer with Cu K radiation (D2-Phaser with LYNXEYE detector, Cu Kα, λ = 1.5414 Å, 30 kV, and 10 mA) to get crystallographic information of the material. The surface electronic states and composition of the as-prepared material were carried out by X-ray photoelectron spectroscopy (XPS, VG ESCALAB MKII instrument) with a Mg Kα X-ray source. All binding energies were referenced to the C 1s peak (284.5 eV) arising from adventitious hydrocarbons.(52) Electrochemical Measurements. Electrochemical measurements were performed in a threeelectrode configuration by using Autolab PGSTAT302 (Eco Chemie, Netherlands) 11 ACS Paragon Plus Environment

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potentiostat workstation equipped with electrochemical impedance spectroscopy (EIS) at room temperature (25ºC). A standard Mercury-mercury oxide (Hg/HgO) reference electrode was used as the reference electrode, while a graphitic rod as a counter electrode. The HER linear polarization curves were recorded in H2-saturated 1.0 M KOH alkaline electrolyte at a sweep rate of 2 mV s-1, while for OER it was O2-saturated. All currents were corrected against ohmic potential drop measured between 10 kHz and 1 MHz. All current density reported in this study was calculated using exposed surface area of the electrode into the electrolyte solution.(53) The onset potential was determined based on the current density of 1.0 mA cm-2 in the recorded LSV curves.(35) The Tafel plots were plotted based on the polarization curves, which were replotted as overpotential vs log(current density) and the linear portion at lower overpotential is fitted to the Tafel equation: (η = blog j + a, where η is the overpotential, j is the current density, and b is the Tafel slope).(7) The stability behaviour was examined by recording CV profiles of 1000 cycles in a potential window from -0.922 V to -1.322 V vs. Hg/HgO at 100 mV s-1. Additionally, the long-term durability test was also examined by galvanostatic experiment in 1.0 M KOH at 25 °C by applying a fixed current density to the working electrode for 12 hours. Two-electrode water electrolysis system was used to study the functionality of this material towards water splitting in an open cell containing 1.0 M KOH alkaline solution across a potential window of 1.2 V to 2.2 V at a scan rate of 5 mV s-1. Furthermore, galvanostatic long-term durability was also examined. Electrochemically Active Surface Area (ECSA). The ESCA was measured by double layer capacitance method derived from cyclic voltammetry (CV) in static solution in a potential window where no Faradaic process occurred. After data collection the following equation: Cdl = Ic/ν was used for electrochemical double-layer capacitance, where Cdl was the double-layer capacitance (mF cm-2) of the electroactive materials, Ic was charging current (mA cm-2) and ν was scan rate (mV s-1). The ECSA of a catalyst sample was calculated from the double layer 12 ACS Paragon Plus Environment

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capacitance according to the following equation: ESCA = Cdl/Cs, where Cs was the specific capacitance reported to be 0.040 mF cm−2 in 1 M NaOH.(46) Electrode Preparation. For comparison, precious metal based catalyst: Pt/C (50 wt% GasHub Technology) was measured at the same condition and approximately similar loading. The ink of Pt/C was prepared by mixing 5 mg of catalyst into 1 mL solution of 0.985 mL ethanol and 0.015 mL (5 wt% Nafion solution) and ultrasonicated for 30 minutes. Afterwards, the ink was cast dropped into pretreated NF until a loading of 2.8 mg cm-2 is achieved. The Pt-modified NF was dried overnight at 80 oC prior to electrochemical measurements. The loading of tungsten-nickel binary catalyst on NF was calculated as follows:(24,50) the weight of NF was measured before hydrothermal treatment and after annealing process. And the increment (z mg) was the loading of tungsten-nickel particles. WNiloading = z mg x (MNiW/MW) = z mg x ((183.8 + 58.6))/183.8) = z mg x 1.3. And approximately it came out to be 2.8 mg cm-2. Calibration of Hg/HgO electrode and conversion versus RHE. The calibration of Hg/HgO electrode was performed in a 1.0 M KOH prepurged and saturated with high purity H2 standard three-electrode system. Linear scanning voltammetry (LSV) was then run at a scan rate of 1.0 mV s−1 and the potential at which the current crossed zero was taken to be the thermodynamic potential for the hydrogen electrode reactions.(54) The zero current point was observed at -0.922 V and thus the following equation was used for conversion versus RHE: E (RHE) = E (Hg/HgO) + 0.922 V. This value is in agreement with calculated value: E vs. RHE = E vs. Hg/HgO + 0.095 + 0.059 pH.(55) DFT Calculations. First-principle calculations were carried out by using the Vienna ab initio simulation package (VASP) based on the all-electron projected augmented wave (PAW) Method.(56-57) The generalized gradient approximation (GGA) with the Perdew-BurkeErnzerhof (PBE) parameterization was employed for the exchange-correlation functional. The 13 ACS Paragon Plus Environment

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3-layer Ni (111) and WNi (111) surfaces were used as the model for Ni and WNi (1:1) in present calculations. To prevent the artificial interaction between repeated slab along zdirection, 15 Ǻ vacuum was introduced with correction of the dipole moment. During structural optimization, the bottom layers of the slab were fixed at the bulk truncated position, while the top two layers and the adsorbates were fully relaxed. The reaction barriers were calculated using climbing image nudged elastic band (CINEB) method.(57-58) And the final transition state (TS) structures were refined by using a quasi-Newton algorithm until the forces were less than 0.03 eV/Å.

For HER reaction, the free energy change for H* adsorption on Ni and WNi surfaces (∆GH) was calculated as follows,

∆GH = Etotal - Esur - EH2/2 + ∆EZPE-T∆S where Etotal was the total energy for the adsorption state, Esur was the energy of pure surface, EH2 was the energy of H2 in gas phase, ∆EZPE was the zero-point energy change and ∆S was the entropy change. ASSOCIATED CONTENT Supporting Information The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acsanm.xxx Digital images, SEM images, Enlarged XRD analysis, EDX, XPS spectra, Hg/HgO reference electrode calibration, OER and overall water splitting performance, HER catalytic activity in acidic medium, EIS plots, cyclic voltammograms, and a table for performance comparison (PDF) AUTHOR INFORMATION

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Corresponding Authors *W.X.: e-mail, [email protected]; B.Y.X.: [email protected]. Notes The authors declare no competing financial interest. ACKNOWLEDGMENT This project is funded by the National Research Foundation (NRF), Prime Minister’s Office, Singapore under its Campus for Research Excellence and Technological Enterprise (CREATE) programme. We also acknowledge financial support from the academic research fund AcRF tier 1 (M4011784 RG 6/17) and tier 2 (M4020246, ARC10/15), Ministry of Education, Singapore. The financial support by National 1000 Young Talents Program of China, the Innovation Foundation of Shenzhen Government (JCYJ20160408173202143), the Fundamental Research Funds for the Central Universities (2017KFXKJC002) and the Innovation Research Funds of Huazhong University of Science and Technology (2017KFYXJJ164) are also acknowledged. REFERENCES 1.

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Figures and Captions

Figure

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Scheme

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WNi/NF450

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Figure 2. (a) Low-magnification SEM images of products after hydrothermal treatment and dried at 80 oC. Inset of Figure 2a is the corresponding High-resolution SEM image. (b) FESEM image of tungsten-nickel/NF hybrid after annealing at 450 oC (WNi/NF450). Inset is a single WNi particle. (c) TEM image of WNi particle (i), (ii) High-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM) image of a portion of WNi particle after annealing at 450 oC. (iii) and (iv) Corresponding mapping for Ni and W, respectively. (d) HRTEM image of a single WNi particle. The inset is the corresponding selected-area diffraction (SAED) pattern of WNi particle (Figure 2c i).

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Figure 3. (a) XRD patterns of WNi/NF600, WNi/NF450 and WNi/NF80 composite before annealing. (b) XPS survey spectrum of WNi/NF450 catalyst. (c) High-resolution XPS spectra of Ni 2p of bare Ni foam and WNi/NF450 catalyst. (d) High-resolution XPS spectrum of W 4f of WNi/NF450 catalyst.

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Figure 4. (a) iR-corrected polarization curves and (b) Tafel plots of WNi/NF450, bare Ni foam and Pt/C loaded on Ni foam at a scan rate of 2 mV s-1. (c) iR-corrected polarization curves of WNi/NF80, WNi/NF300, WNi/NF450 and WNi/NF600 materials. (d) Overpotentials required to deliver 10 mA cm-2 current density and Tafel slopes for catalyst annealed at different temperatures.

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Figure 5. (a,b) Electrochemical stability tests: (a) Chronopotentiometric curve of WNi/NF450 in a three-electrode configuration with a constant current density of 20 mA cm-2 without iR correction, and (b) iR-corrected polarization curves of WNi/NF450 initially and after 1000 cycles. The inset of Figure 5b shows the corresponding Tafel plots before (in solid line) and after 1000 cycles (in doted line). (c and d) DFT calculation: (c) Reaction pathways for O-H bond breaking of H2O molecule, activated H2O adsorption, OH adsorption and H adsorption at W (black line) and Ni (red line) site on WNi (111) surfaces. (d) The calculated free energy diagram for hydrogen evolution on WNi (111) and Ni (111) surfaces.

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ToC figure An efficient and robust WNi on Ni foam electrocatalyst is prepared by a facile method and exhibits an outstanding activity and remarkable stability for alkaline water electrolysis. DFT calculation reveals a lower adsorption energy of water molecule and a smaller Gibbs free energy of H adsorption on WNi surface, which would contribute to an enhanced kinetics for water electrolysis.

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