To relieve our strong reliance on fossil fuels and to reduce greenhouse effects, there is an ever-growing interest in using electrocatalytic water splitting to produce green, renewable, and environment-benign hydrogen fuel via the hydrogen evolution reaction. For commercially feasible water electrolysis, it is imperative to develop electrocatalysts that perform as efficiently as Pt but using only earth-abundant commercial materials. However, the highest performance current catalysts consist of nanostructures made by using complex methods. Here we report a porous nickel diselenide (NiSe_2) catalyst that is superior for water electrolysis, exhibiting much better catalytic performance than most first-row transition metal dichalcogenide-based catalysts, well-studied MoS_2, and WS_2-based catalysts. Indeed NiSe2 performs comparably to the state-of-the-art Pt catalysts. We fabricate NiSe_2 directly from commercial nickel foam by acetic acid-assisted surface roughness engineering. To understand the origin of the high performance, we use first-principles calculations to identify the active sites. This work demonstrates the commercial possibility of hydrogen production via water electrolysis using porous bulk NiSe_2 catalysts

Bao, Jiming

Chen, Shuo

Goddard, William A., III

He, Ran

Liu, Yuanyue

Ren, Zhifeng

Sun, Jingying

Yu, Fang

Zhou, Haiqing

Zhu, Zhuan

Caltech Authors - Main

Supporting Information
Outstanding hydrogen evolution reaction catalyzed by porous nickel diselenide 
electrocatalysts**
Haiqing Zhou, Fang Yu, Yuanyue Liu, Jingying Sun, Zhuan Zhu, Ran He, Jiming Bao, William A. 
Goddard III, Shuo Chen*, Zhifeng Ren*
* Correspondence and requests for materials should be addressed to S. C. schen34@uh.edu or Z. F. R. 
zren@uh.edu.
1. Methods
Material synthesis. The commercially purchased Ni foam was cut into small pieces with an area of 1 
cm2, which were then immersed into the PVP/HAc solution (0.1 g PVP in 5 ml HAc) for several seconds. 
After drying it slowly, they were placed in the center of a tube furnace, followed by direct selenization at 
600 oC for 1h in Ar atmosphere with the Se powder placed at the upstream as Se source. 
Electrochemical tests. Electrochemical tests were carried out in a N2-saturated three-electrode 
system (Gamry, Reference 600),1,2 where a saturated calomel electrode was used as the reference 
electrode, a Pt wire as the counter electrode and as-prepared NiSe2 foams directly as the working 
electrode. To exclude the possible contribution of any Pt contamination to the catalytic performance, we 
performed similar measurements using a graphite foil (Alfa Aesar) as the counter electrode, and XPS 
analysis on several positions of the catalyst surface, where no Pt signals are found on post-HER catalysts. 
Electronic Supplementary Material (ESI) for Energy & Environmental Science.
This journal is © The Royal Society of Chemistry 2017
50-100 potential sweeps between 0.07 V to -0.20 V vs. reversible hydrogen electrode (RHE) at a scan rate 
of 50 mV/s were applied to electrochemically activate the catalysts prior to the HER measurements and 
for studying the electrochemical stability. The electrochemical impedance spectroscopy curves were 
collected at a potential of -0.14 V vs. RHE in the same device configuration by tuning the frequency from 
10 mHz to 1 MHz with a 10 mV AC dither.
Computational methods. To identify the active site for HER, we performed Density Functional 
Theory (DFT) calculations using the Vienna Ab-initio Simulation Package (VASP)3,4 with projector 
augmented wave (PAW) pseudopotentials5,6 and the Perdew-Burke-Ernzerhof (PBE) exchange-
correlation functional.7 We used 400 eV for the plane-wave cutoff, and fully relaxed the systems until the 
final force on each atom is less than 0.01 eV/Å. We have doubled checked the free energies of H 
adsorption on perfect surface and vacancy-containing surfaces using 500 eV, and found the values differ 
by < 10 meV. We used a slab of 2×2 surface supercell, with a thickness of 4 stoichiometric layers, and 
5×5×1 Monkhorst-Pack k-points sampling.8 Following the approach of Ref. 9 and 10, the free energy of 
hydrogen adsorption (ΔGH*) is calculated as ΔGH* = Ead +ΔEZP + TS, where Ead is the adsorption energy 
of H onto the surface, referenced to the 1/2 of energy of the H2 moleccule (see below), EZP is the 
difference in zero point energy between the adsorbed H and the H2 molecule, T is the room temperature, 
and S is the 1/2 entropy of H2 molecule at standard conditions. The adsorption energy Ea is calculated as 
Ea = E(H+surface) - E(surface) - E(H2)/2, where E(H+surface), E(surface) and E(H2) are the energies of 
H-adsorbed surface, pure surface, and an H2 molecule, respectively.
2. SEM morphologies of porous NiSe2 catalyst from original Ni foam
Figure S1. Low and high-magnification SEM images of as-prepared NiSe2 foam from commercial Ni 
foam without any treatment.
3. Energy dispersive X-ray spectrum (EDS) of as-grown NiSe2 catalyst
Figure S2. a, Elemental EDS mapping of Ni (yellow) and Se (purple) elements in the same image. b, 
Original EDS analysis on the chemical composition of as-prepared NiSe2 foam from HAc and PVP co-
treated Ni foam under TEM.
4. XPS spectra of different as-prepared NiSe2 catalysts
Figure S3. XPS spectra of different NiSe2 foams.
5. Comparison of the catalytic performance of HP-NiSe2 catalysts between Pt and graphite foil 
counter electrode
Figure S4. The polarization curves of the HP-NiSe2 catalysts when using Pt or graphite foil as counter 
electrode. No obvious differences are detected during the measurements.
6. The summary of the catalytic performance for porous NiSe2 catalysts
Table S1. The main performance parameters of different NiSe2 foams in comparison with a Pt wire 
investigated in Figure 3. Here j0,,η10 and η100 are corresponding to the exchange current density, the 
potentials vs RHE at 10 mA cm-2, and 100 mA cm-2, respectively.
Catalyst Tafel slope j0 η10 η100
A-NiSe2 46.0 mV dec-1 8.6 μA cm-2 153 mV 200 mV
H-NiSe2 42.6 mV dec-1 64.6 μA cm-2 107 mV 153 mV
HP-NiSe2 43.0 mV dec-1 612.0 μA cm-2 57 mV 103 mV
Pt wire 31.0 mV dec-1 1126.2 μA cm-2 32 mV 72 mV
7. The comparison of our catalystswith other reported cheap electrocatalysts
Table S2. The comparison on the HER performance of our catalysts with other available cheap HER 
electrocatalysts in the literatures. These values j0, η10, and η100 represent the exchange current density, the 
potentials vs RHE at 10 mA/cm2 and 100 mA/cm2, respectively.
Catalyst Tafel slope η10 η100 j0 Source
NA: not provided in the data.
8. Double-layer capacitance measurements
Benchmark Pt 31.0 mV dec-1 32 mV 72 mV 1126.2 μA cm-2 This work
HP-NiSe2 foam 43.0 mVdec-1 57 mV 103 mV 612.0 μA cm-2 This work
MoS2(1-x)Se2x/NiSe2 42.0 mVdec-1 69 mV 112 mV 299.4 μA cm-2 2
MoSx/N-CNT 40 mVdec-1 110 mV 225 mV 33.1 μA cm-2 11
NiSe2 nanosheets/CC 32 mVdec-1 117 mV NA 4.7 μA cm-2 12
CoS2/RGO-CNT 51 mVdec-1 142 mV 178 mV 62.6 μA cm-2 13
FeS2 nanosheets 46 mVdec-1 108 mV 170 mV 5.5 μA cm-2 14
CoSe2/carbon fiber 42 mVdec-1 139 mV 184 mV 6μA cm-2 15
WS1.56Se0.44 nanoribbons 68 mVdec-1 176 mV NA 25 μA cm-2 16
Ni5P4-Ni2P nanosheets 79 mVdec-1 120 mV 200 mV 116 μA cm-2 17
Ni2P nanoparticles 46 mVdec-1 105 mV 180 mV 33 μA cm-2 18
CoP nanowire array/CC 51 mVdec-1 67 mV 204 mV 288 μA cm-2 19
Mo-W-P nanosheets/CC 52 mVdec-1 100 mV 138 mV 288 μA cm-2 20
Metallic WO2/carbon 46 mVdec-1 58 mV NA 640 μA cm-2 21
MoO2/PC-RGO 41 mVdec-1 64 mV NA 480 μA cm-2 22
CoPS NPls/carbon paper 56 mVdec-1 48 mV NA 984 μA cm-2 23
CoPS NWs/carbon paper 48 mVdec-1 61 mV NA 554 μA cm-2 23
MoS2/N-RGO 41.3 mVdec-1 56 mV NA 720 μA cm-2 24
Figure S5. Electrochemical cyclic voltammetry curves of different NiSe2 foams with different scan rates. 
a, A-NiSe2 foam with scan rates ranging from 20 mV/s to 200 mV/s with a step of 20 mV/s. b, H-NiSe2 
foam with scan rates from 5 mV/s to 50 mV/s with a 5 mV/s interval. c, HP-NiSe2 foam with scan rates 
ranging from 2 mV/s to 20 mV/s with an interval point of 2 mV/s. The potential is scanned from 0.1 to 
0.2 V vs RHE where no faradic current was detected.
9. Electrical conductivity measurements of bulk NiSe2 crystals
Figure S6. (a) XRD pattern and (b) electrical resistivity measurements of a bulk NiSe2 sample prepared 
by mechanical alloying of high-purity Ni and Se powders by a high-energy ball mill (SPEX 8000D) for 
20 h and hot pressing at 773 K for 2 min.
10. Data for Fig. 4 and structure of the NiSe2 slab (in VASP CONTCAR format)
perfect V-Ni V-Se V-2Se ad-Ni ad-Se ad-2Se
Free 
energy(eV/H)
0.68 0.39 0.38 0.47 0.71 0.09 -0.01
NiSe2
   1.00000000000000     
    11.8719999999999999    0.0000000000000000    0.0000000000000000
     0.0000000000000000   11.8719999999999999    0.0000000000000000
     0.0000000000000000    0.0000000000000000   20.0000000000000000
   Ni   Se
    32    64
Selective dynamics
Direct
  0.0066675993522886 -0.0004355373005453  0.2999600727090445   T   TT
 -0.0001573366221758  0.9964795028284821  0.5978825527890403   T   TT
  0.2499012177917495 -0.0031784384313857  0.4442511860497020   T   TT
0.2567799758378674  0.9986516520039094  0.7421057312696081   T   TT
0.2432973852295297  0.2495747208374209  0.2999697633520752   T   TT
0.2501173976560165  0.2464663422859265  0.5978950253180432   T   TT
0.0000848300246491  0.2468096293625826  0.4442550960502816   T   TT
0.9931873788988308  0.2486366513258388  0.7421053277570332   T   TT
0.0067043028102850  0.4995737853818545  0.2999353701053446   T   TT
 -0.0001298464554059  0.4964721527274584  0.5978796696135562   T   TT
0.2498971985875931  0.4968145778524392  0.4442449734775105   T   TT
0.2568089549908256  0.4986335901639650  0.7420910833837595   T   TT
0.2433021255599140  0.7496188376144860  0.2999641487087098   T   TT
0.2501027529849907  0.7464764389217743  0.5978844609956306   T   TT
0.0000917638536297  0.7468215031264130  0.4442460897100310   T   TT
0.9931762041351612  0.7486665555319038  0.7420949265791846   T   TT
  0.5067064339616435 -0.0004266420373065  0.2999536711075301   T   TT
0.4998460786650789  0.9964652581750038  0.5978864022950832   T   TT
  0.7499102865149861 -0.0031877719648247  0.4442443633147298   T   TT
0.7567804537390733  0.9986501639412766  0.7421033000407599   T   TT
0.7432972336757780  0.2495646864052058  0.2999535705460435   T   TT
0.7501171792452987  0.2464816160993655  0.5978922480052052   T   TT
0.5000968095526603  0.2468125008092458  0.4442432347618467   T   TT
0.4931954618372723  0.2486353002224210  0.7421012516904474   T   TT
0.5066639486845046  0.4995791564660371  0.2999554306212046   T   TT
0.4998591017430232  0.4964796890511174  0.5978810304384220   T   TT
0.7499048370558340  0.4968222699209380  0.4442457222550898   T   TT
0.7567820392772402  0.4986481314187219  0.7420953472505711   T   TT
0.7433184301608693  0.7495736242801179  0.2999393646666617   T   TT
0.7501097081881132  0.7464520642833561  0.5978715305711257   T   TT
0.5001204646828332  0.7468298456148145  0.4442425102431442   T   TT
0.4931954578915905  0.7486381865746357  0.7421035469802468   T   TT
0.1907927969786359  0.1880541082591476  0.4117010696567121   T   TT
0.1901240492343139  0.1910094273591115  0.7214824237164089   T   TT
0.0654943068864851  0.3201315201670959  0.2563990355433776   T   TT
0.0616483255181409  0.3089730156614333  0.5607428114751568   T   TT
0.4382734752528953  0.0591782693844061  0.4813546495431387   T   TT
0.4345344224450297  0.0693235887129809  0.7857177870107539   T   TT
0.3098055216515955  0.4418072382557047  0.3206788003882028   T   TT
0.3091934879496128  0.4375878979398209  0.6304944851914969   T   TT
0.3117391337281156  0.3091985459275519  0.4813517223413623   T   TT
0.3154304176215944  0.3193094517882245  0.7857234113765283   T   TT
0.4401632965040815  0.1918024362855373  0.3206766445655260   T   TT
0.4408151279048972  0.1875763918870014  0.6304884411473085   T   TT
0.0591931825569547  0.4380453468232652  0.4116952597259013   T   TT
0.0598582551509802  0.4410091579621155  0.7214731202646336   T   TT
0.1845089154489411  0.0701504821939064  0.2564412920472130   T   TT
0.1883227815738421  0.0589622981282898  0.5607504511263314   T   TT
0.1907845473173868  0.6880422699905895  0.4116918424394442   T   TT
0.1901017132084825  0.6909583376680670  0.7214708668304328   T   TT
0.0655054031783750  0.8201360171669303  0.2564570429851847   T   TT
0.0616281092922571  0.8089659038567116  0.5607537832990638   T   TT
0.4382679532654134  0.5591487870953404  0.4813592356828884   T   TT
0.4345601618797899  0.5693021905892026  0.7857130462359814   T   TT
0.3098389000428427  0.9418020752203080  0.3206971924977297   T   TT
0.3091606441510620  0.9376046176444035  0.6304731045066628   T   TT
0.3117338346394587  0.8091688834998868  0.4813540871290615   T   TT
0.3154175588899016  0.8193016184854949  0.7857164804727512   T   TT
0.4401799252041339  0.6918290029186221  0.3206988409518404   T   TT
0.4407904428212158  0.6875988957005982  0.6304696779245298   T   TT
0.0591888657781381  0.9380713428028414  0.4116970084732689   T   TT
0.0598580685411532  0.9410167134243548  0.7214723815480248   T   TT
0.1845386031740807  0.5701442117764831  0.2564067193881803   T   TT
0.1883295214683958  0.5589669181277239  0.5607573572598141   T   TT
0.6907903039682503  0.1880586417204357  0.4116867631148922   T   TT
0.6901334886223732  0.1909827088446823  0.7214841925142834   T   TT
0.5654844178423125  0.3201250622804722  0.2564049463806853   T   TT
0.5616447910445674  0.3089588160885678  0.5607510506675475   T   TT
0.9382614956887729  0.0591600588299648  0.4813632082713937   T   TT
0.9345704151888586  0.0693059465126342  0.7857099229220765   T   TT
0.8098323496788763  0.4417948675768673  0.3206749013780870   T   TT
0.8092131232492673  0.4375884051035964  0.6304774596008289   T   TT
0.8117227373637743  0.3091650971237694  0.4813512999135273   T   TT
0.8154390960495758  0.3193053949275121  0.7857191884930221   T   TT
0.9401735469030668  0.1918165242740675  0.3206803107843350   T   TT
0.9407802795686209  0.1875980880700108  0.6304705262947893   T   TT
0.5591895258608022  0.4380254619596619  0.4116906921646882   T   TT
0.5598749638151488  0.4409617888717802  0.7214651306412450   T   TT
0.6845155943607977  0.0701521541125364  0.2563890928069552   T   TT
0.6883245108402770  0.0589609389730473  0.5607606985175621   T   TT
0.6907928027439331  0.6880434905669380  0.4116849724032006   T   TT
0.6901220056106002  0.6909645776734742  0.7214729440377659   T   TT
0.5655001000555500  0.8201455096499601  0.2564192727345181   T   TT
0.5616450033776776  0.8089754943179465  0.5607444708306982   T   TT
0.9382712819849818  0.5591628963709566  0.4813532242279144   T   TT
0.9345439569257222  0.5693333761092404  0.7857059193933913   T   TT
0.8098414292983948  0.9417958949554656  0.3206489539350427   T   TT
0.8091619346508335  0.9375940438711092  0.6304768472966098   T   TT
0.8117526509632023  0.8091401843513990  0.4813513926163112   T   TT
0.8154230525620177  0.8193016496835899  0.7857164528301454   T   TT
0.9401905271530422  0.6917975698632581  0.3206757459046545   T   TT
0.9407868164150627  0.6875933064051533  0.6304707395936480   T   TT
0.5592080123492229  0.9380657619104064  0.4116782894191566   T   TT
0.5598618224287812  0.9410138190517696  0.7214843827920081   T   TT
0.6844921077911069  0.5701213795585953  0.2564245044986694   T   TT
0.6883318078720868  0.5589735181576025  0.5607544276187836   T   TT
References:
1 H. Q. Zhou, Y. M. Wang, R. He, F. Yu, J. Y. Sun, F. Wang, Y. C. Lan, Z. F. Ren and S. Chen, Nano 
Energy, 2016, 20, 29-36.
2 H. Q. Zhou, F. Yu, Y. F. Huang, J. Y. Sun, Z. Zhu, R. J. Nielsen, R. He, J. M. Bao, W. A. Goddard III, 
S. Chen and Z. F. Ren, Nat. Commun., 2016, 7, 12765.
3 G. Kresse and J. Hafner, Phys. Rev. B, 1993, 47, 558-561.
4 G. Kresse and J. Furthmüller, Phys. Rev. B, 1996, 54, 11169-11186.
5 G. Kresse and D. Joubert, Phys. Rev. B, 1999, 59, 1758-1775.
6 P. E. Blöchl, Phys. Rev. B, 1994, 50, 17953-17979.
7 J. P. Perdew, K. Burke and M. Ernzerhof, Phys. Rev. Lett., 1996, 77, 3865-3868.
8 H. J. Monkhorst and J. D. Pack, Phys. Rev. B, 1976, 13, 5188-5192.
9 B. Hinnemann, P. G. Moses, J. Bonde, K. P. Jørgensen, J. H. Nielsen, S. Horch, I. Chorkendorff and J. 
K. Nørskov, J. Am. Chem. Soc., 2005, 127, 5308-5309.
10 J. K. Nørskov, T. Bligaard, A. Logadottir, J. R. Kitchin, J. G. Chen, S. Pandelov and U. Stimming, J. 
Electrochem. Soc., 2005, 152, J23-J26.
11 D. J. Li, U. N. Maiti, J. Lim, D. S. Choi, W. J. Lee, Y. Oh, G. Y. Lee and S. O. Kim, Nano Lett., 2014, 
14, 1228-1233.
12 F. M. Wang, Y. C. Li, T. A. Shifa, K. L. Liu, F. Wang, Z. X. Wang, P. Xu, Q. S. Wang and J. He, 
Angew. Chem. Int. Ed., 2016, 55, 6919-6924.
13 S. J. Peng, L. L. Li, X. P. Han, W. P. Sun, M. Srinivasan, S. G. Mhaisalkar, F. Y. Cheng, Q. Y. Yan, J. 
Chen and S. Ramakrishna, Angew. Chem. Int. Ed., 2014, 126, 12802-12807.
14 D. Y. Wang, M. Gong, H. L. Chou, C. J. Pan, H. A. Chen, Y. Wu, M. C. Lin, M. Guan, J. Yang, C. W. 
Chen, Y. L. Wang, B. J. Hwang, C. C. Chen and H. J. Dai, J. Am. Chem. Soc., 2015, 137, 1587-1592.
15 D. S. Kong, H. T. Wang, Z. Y. Lu and Y. Cui, J. Am. Chem. Soc., 2014, 136, 4897-4900.
16 F. M. Wang, J. S. Li, F. Wang, T. A. Shifa, Z. Z. Cheng, Z. X. Wang, K. Xu, X. Y. Zhan, Q. S. Wang, 
Y. Huang, C. Jiang and J. He, Adv. Funct. Mater., 2015, 25, 6077-6083.
17 X. G. Wang, Y. V. Kolen’ko, X. Q. Bao, K. Kovnir and L. F. Liu, Angew. Chem. Int. Ed., 2015, 54, 
8188-8192.
18 E. J. Popczun, J. R. McKone, C. G. Read, A. J. Biacchi, A. M. Wiltrout, N. S. Lewis and R. E. Schaak, 
J. Am. Chem. Soc., 2013, 135, 9267-9270.
19 J. Q. Tian, Q. Liu, A. M. Asiri and X. P. Sun, J. Am. Chem. Soc., 2014, 136, 7587-7590.
20 X. D. Wang, Y. F. Xu, H. S. Rao, W. J. Xu, H. Y. Chen, W. X. Zhang, D. B. Kuang and C. Y. Su, 
Energy Environ. Sci., 2016, 9, 1468-1475.
21 R. Wu, J. F. Zhang, Y. M. Shi, D. L. Liu and B. Zhang, J. Am. Chem. Soc., 2015,137, 6983-6986.
22 Y. J. Tang, M. R. Gao, C. H. Liu, S. L. Li, H. L. Jiang, Y. Q. Lan, M. Han and S. H. Yu, Angew. 
Chem. Int. Ed., 2015, 54, 12928-12932.
23 M. Cabán-Acevedo, M. L. Stone, J. R. Schmidt, J. G. Thomas, Q. Ding, H. C. Chang, M. L. Tsai, J. H. 
He and S. Jin, Nat. Mater., 2015, 14, 1245-1251.
24 Y. J. Tang, Y. Wang, X. L. Wang, S. L. Li, W. Huang, L. Z. Dong, C. H. Liu, Y. F. Li and Y. Q. Lan, 
Adv. Energy Mater., 2016, 6, 1600116.


Outstanding hydrogen evolution reaction catalyzed by porous nickel diselenide electrocatalysts

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Outstanding hydrogen evolution reaction catalyzed by porous nickel diselenide electrocatalysts

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