Recent advances and future prospects on Ni<sub>3</sub>S<sub>2</sub>-Based electrocatalysts for efficient alkaline water electrolysis

Shiwen Wang; Zhen Geng; Songhu Bi; Yuwei Wang; Zijian Gao; Liming Jin; Cunman Zhang

doi:10.1016/j.gee.2023.02.011

Volume 9 Issue 4

Apr. 2024

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Article Navigation > Green Energy&Environment > 2024 > 9(4): 659-683

Shiwen Wang, Zhen Geng, Songhu Bi, Yuwei Wang, Zijian Gao, Liming Jin, Cunman Zhang. Recent advances and future prospects on Ni3S2-Based electrocatalysts for efficient alkaline water electrolysis. Green Energy&Environment, 2024, 9(4): 659-683. doi: 10.1016/j.gee.2023.02.011

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Shiwen Wang, Zhen Geng, Songhu Bi, Yuwei Wang, Zijian Gao, Liming Jin, Cunman Zhang. Recent advances and future prospects on Ni₃S₂-Based electrocatalysts for efficient alkaline water electrolysis. Green Energy&Environment, 2024, 9(4): 659-683. doi: 10.1016/j.gee.2023.02.011

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Recent advances and future prospects on Ni₃S₂-Based electrocatalysts for efficient alkaline water electrolysis

doi: 10.1016/j.gee.2023.02.011

Abstract

Abstract

Green hydrogen (H₂) produced by renewable energy powered alkaline water electrolysis is a promising alternative to fossil fuels due to its high energy density with zero-carbon emissions. However, efficient and economic H₂ production by alkaline water electrolysis is hindered by the sluggish hydrogen evolution reaction (HER) and oxygen evolution reaction (OER). Therefore, it is imperative to design and fabricate high-active and low-cost non-precious metal catalysts to improve the HER and OER performance, which affects the energy efficiency of alkaline water electrolysis. Ni₃S₂ with the heazlewoodite structure is a potential electrocatalyst with near-metal conductivity due to the Ni–Ni metal network. Here, the review comprehensively presents the recent progress of Ni₃S₂-based electrocatalysts for alkaline water electrocatalysis. Herein, the HER and OER mechanisms, performance evaluation criteria, preparation methods, and strategies for performance improvement of Ni₃S₂-based electrocatalysts are discussed. The challenges and perspectives are also analyzed.
- Alkaline water electrolysis,
- Hydrogen,
- Electrocatalysts,
- Ni₃S₂

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References

[1]	T. Reier; H.N. Nong; D. Teschner; R. Schlogl; P. Strasser, Advanced Energy Materials 7 (2017) 1601275.
[2]	C. Liang; P. Zou; A. Nairan; Y. Zhang; J. Liu; K. Liu; S. Hu; F. Kang; H.J. Fan; C. Yang, Energy & Environmental Science 13 (2020) 86-95.
[3]	J.-T. Ren; Y. Yao; Z.-Y. Yuan, Green Energy Environ. 6 (2021) 620-643.
[4]	F. Cheng; J. Chen, Chemical Society Reviews 41 (2012) 2172-2192.
[5]	Y. Cheng; K. Pang; X. Xu; P. Yuan; Z. Zhang; X. Wu; L. Zheng; J. Zhang; R. Song, Carbon 157 (2020) 153-163.
[6]	S. Jiao; X. Fu; S. Wang; Y. Zhao, Energy & Environmental Science 14 (2021) 1722-1770.
[7]	N.K. Chaudhari; H. Jin; B. Kim; K. Lee, Nanoscale 9 (2017) 12231-12247.
[8]	G. Yilmaz; S.B. Peh; D. Zhao; G.W. Ho, Adv Sci (Weinh) 6 (2019) 1901129.
[9]	Q. Zhang; W. Chen; G. Chen; J. Huang; C. Song; S. Chu; R. Zhang; G. Wang; C. Li; K.K. Ostrikov, Applied Catalysis B: Environmental 261 (2020) 118254.
[10]	F.M. Sapountzi; J.M. Gracia; C.J. Weststrate; H.O.A. Fredriksson; J.W. Niemantsverdriet, Progress in Energy and Combustion Science 58 (2017) 1-35.
[11]	N. Mahmood; Y. Yao; J.W. Zhang; L. Pan; X. Zhang; J.J. Zou, Adv Sci (Weinh) 5 (2018) 1700464.
[12]	K. Zeng; D. Zhang, Progress in energy and combustion science 36 (2010) 307-326.
[13]	H.A. Miller; K. Bouzek; J. Hnat; S. Loos; C.I. Bernacker; T. Weissgarber; L. Rontzsch; J. Meier-Haack, Sustainable Energy & Fuels 4 (2020) 2114-2133.
[14]	C. Ling; L. Shi; Y. Ouyang; X.C. Zeng; J. Wang, Nano letters 17 (2017) 5133-5139.
[15]	J. Wang; H.-X. Zhong; Z.-L. Wang; F.-L. Meng; X.-B. Zhang, ACS nano 10 (2016) 2342-2348.
[16]	P. Chen; T. Zhou; M. Zhang; Y. Tong; C. Zhong; N. Zhang; L. Zhang; C. Wu; Y. Xie, Advanced Materials 29 (2017) 1701584.
[17]	Y. Chen; S. Ji; C. Chen; Q. Peng; D. Wang; Y. Li, Joule 2 (2018) 1242-1264.
[18]	O. Kasian; J.P. Grote; S. Geiger; S. Cherevko; K.J. Mayrhofer, Angewandte Chemie International Edition 57 (2018) 2488-2491.
[19]	H. Zhang; Y. Liu; T. Chen; J. Zhang; J. Zhang; X.W. Lou, Advanced Materials 31 (2019) 1904548.
[20]	Y. Zhang; B. Ouyang; J. Xu; S. Chen; R.S. Rawat; H.J. Fan, Advanced Energy Materials 6 (2016) 1600221.
[21]	Y. Zhu; G. Chen; Y. Zhong; W. Zhou; Z. Shao, Advanced Science 5 (2018) 1700603.
[22]	J.Y. Huot; M. Trudeau; R. Schulz, Journal of the Electrochemical Society 138 (1991) 1316.
[23]	R.B. Patil; A. Mantri; S.D. House; J.C. Yang; J.R. Mckone, ACS Applied Energy Materials 2 (2019) 2524-2533.
[24]	H. Jin; J. Wang; D. Su; Z. Wei; Z. Pang; Y. Wang, Journal of the American Chemical Society 137 (2015) 2688-2694.
[25]	Y. Li; C. Zhao, ACS Catalysis 7 (2017) 2535-2541.
[26]	D. Likius; A. Rahman; C. Zivayi; V. Uahengo, Catalysis Letters 150 (2020) 1942-1956.
[27]	F. Du; L. Shi; Y. Zhang; T. Li; J. Wang; G. Wen; A. Alsaedi; T. Hayat; Y. Zhou; Z. Zou, Applied Catalysis B: Environmental 253 (2019) 246-252.
[28]	J. Zhang; Y. Li; T. Zhu; Y. Wang; J. Cui; J. Wu; H. Xu; X. Shu; Y. Qin; H. Zheng; P.M. Ajayan; Y. Zhang; Y. Wu, ACS Appl Mater Interfaces 10 (2018) 31330-31339.
[29]	K. Xu; H. Cheng; H. Lv; J. Wang; L. Liu; S. Liu; X. Wu; W. Chu; C. Wu; Y. Xie, Advanced Materials 30 (2018) 1703322.
[30]	C. Lei; S. Lyu; J. Si; B. Yang; Z. Li; L. Lei; Z. Wen; G. Wu; Y. Hou, ChemCatChem 11 (2019) 5855-5874.
[31]	X. Peng; C. Pi; X. Zhang; S. Li; K. Huo; P.K. Chu, Sustainable Energy & Fuels 3 (2019) 366-381.
[32]	R.Q. Yao; Y.T. Zhou; H. Shi; W.B. Wan; Q.H. Zhang; L. Gu; Y.F. Zhu; Z. Wen; X.Y. Lang; Q. Jiang, Advanced Functional Materials 31 (2021) 2009613.
[33]	H. Zhou; Y. Wang; R. He; F. Yu; J. Sun; F. Wang; Y. Lan; Z. Ren; S. Chen, Nano Energy 20 (2016) 29-36.
[34]	L. Liao; Y. Zhao; H. Zhou; D. Li; Y. Qi; Y. Zhang; Y. Sun; Q. Zhou; F. Yu, Small 18 (2022) e2203171.
[35]	H. Zhou; F. Yu; Y. Huang; J. Sun; Z. Zhu; R.J. Nielsen; R. He; J. Bao; W.A. Goddard, Iii; S. Chen; Z. Ren, Nat Commun 7 (2016) 12765.
[36]	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; H. Dai, J Am Chem Soc 137 (2015) 1587-1592.
[37]	F. Zhang; Y. Liu; F. Yu; H. Pang; X. Zhou; D. Li; W. Ma; Q. Zhou; Y. Mo; H. Zhou, ACS Nano 17 (2023), 1681-1692.
[38]	X. Zhou; Y. Mo; F. Yu; L. Liao; X. Yong; F. Zhang; D. Li; Q. Zhou; T. Sheng; H. Zhou, Advanced Functional Materials (2022).
[39]	R. Zhang; X. Wang; S. Yu; T. Wen; X. Zhu; F. Yang; X. Sun; X. Wang; W. Hu, Advanced Materials 29 (2017).
[40]	T. Liu; P. Li; N. Yao; G. Cheng; S. Chen; W. Luo; Y. Yin, Angew Chem Int Ed Engl 58 (2019) 4679-4684.
[41]	J. Li; M. Yan; X. Zhou; Z.-Q. Huang; Z. Xia; C.-R. Chang; Y. Ma; Y. Qu, Advanced Functional Materials 26 (2016) 6785-6796.
[42]	B. Liu; Y.F. Zhao; H.Q. Peng; Z.Y. Zhang; C.K. Sit; M.F. Yuen; T.R. Zhang; C.S. Lee; W.J. Zhang, Adv Mater 29 (2017).
[43]	F. Wang; Y. Li; T.A. Shifa; K. Liu; F. Wang; Z. Wang; P. Xu; Q. Wang; J. He, Angew Chem Int Ed Engl 55 (2016) 6919-6924.
[44]	A.T. Swesi; J. Masud; M. Nath, Energy & Environmental Science 9 (2016) 1771-1782.
[45]	X. Xia; L. Wang; N. Sui; V.L. Colvin; W.W. Yu, Nanoscale 12 (2020) 12249-12262.
[46]	Z. Chen; Y. Song; J. Cai; X. Zheng; D. Han; Y. Wu; Y. Zang; S. Niu; Y. Liu; J. Zhu; X. Liu; G. Wang, Angew Chem Int Ed Engl 57 (2018) 5076-5080.
[47]	F. Song; W. Li; J. Yang; G. Han; P. Liao; Y. Sun, Nat Commun 9 (2018) 4531.
[48]	X. Zhang; F. Zhou; W. Pan; Y. Liang; R. Wang, Advanced Functional Materials 28 (2018).
[49]	L.-L. Feng; G. Yu; Y. Wu; G.-D. Li; H. Li; Y. Sun; T. Asefa; W. Chen; X. Zou, Journal of the American Chemical Society 137 (2015) 14023-14026.
[50]	Y. Liu; Q. Li; R. Si; G.D. Li; W. Li; D.P. Liu; D. Wang; L. Sun; Y. Zhang; X. Zou, Advanced Materials 29 (2017) 1606200.
[51]	J. Yoo; I.H. Kwak; I.S. Kwon; K. Park; D. Kim; J.H. Lee; S.A. Lim; E.H. Cha; J. Park, Journal of Materials Chemistry C 8 (2020) 3240-3247.
[52]	X. Zheng; X. Han; Y. Zhang; J. Wang; C. Zhong; Y. Deng; W. Hu, Nanoscale 11 (2019) 5646-5654.
[53]	N. Jiang; Q. Tang; M. Sheng; B. You; D.-E. Jiang; Y. Sun, Catalysis Science & Technology 6 (2016) 1077-1084.
[54]	J.N. Hausmann; P.W. Menezes, Angew Chem Int Ed Engl 61 (2022) e202207279.
[55]	S. Anantharaj; S. Noda, International Journal of Hydrogen Energy 45 (2020) 15763-15784.
[56]	H. Sun; X. Xu; H. Kim; W. Jung; W. Zhou; Z. Shao, Energ. Enviro. Mat. e12441.
[57]	M. Durovic; J. Hnat; K. Bouzek, Journal of Power Sources 493 (2021).
[58]	E. Liu; J. Li; L. Jiao; H.T.T. Doan; Z. Liu; Z. Zhao; Y. Huang; K.M. Abraham; S. Mukerjee; Q. Jia, J Am Chem Soc 141 (2019) 3232-3239.
[59]	N. Danilovic; R. Subbaraman; D. Strmcnik; K.C. Chang; A.P. Paulikas; V.R. Stamenkovic; N.M. Markovic, Angew Chem Int Ed Engl 51 (2012) 12495-12498.
[60]	B. Liu; Y. Zhao; H. Peng; Z. Zhang; C. Sit; M. Yuen; T. Zhang; C. Lee; W. Zhang; N.C. Diselenide, Adv. Mater 29 (2017) 1606521.
[61]	A. Lasia, International Journal of Hydrogen Energy 44 (2019) 19484-19518.
[62]	J. Mahmood; F. Li; S.M. Jung; M.S. Okyay; I. Ahmad; S.J. Kim; N. Park; H.Y. Jeong; J.B. Baek, Nat Nanotechnol 12 (2017) 441-446.
[63]	D. Strmcnik; M. Uchimura; C. Wang; R. Subbaraman; N. Danilovic; D. Van Der Vliet; A.P. Paulikas; V.R. Stamenkovic; N.M. Markovic, Nature Chemistry 5 (2013) 300-306.
[64]	W. Sheng; Z. Zhuang; M. Gao; J. Zheng; J.G. Chen; Y. Yan, Nature communications 6 (2015) 1-6.
[65]	N.T. Suen; S.F. Hung; Q. Quan; N. Zhang; Y.J. Xu; H.M. Chen, Chem Soc Rev 46 (2017) 337-365.
[66]	Y. Kang; F. Zhang; B. Liu; Y. Sun; X. Zhang; W. Song; Y. Wei; Z. Zhao; J. Liu, Physical Chemistry Chemical Physics 22 (2020) 18672-18680.
[67]	W. Cheng; X. Zhao; H. Su; F. Tang; W. Che; H. Zhang; Q. Liu, Nature Energy 4 (2019) 115-122.
[68]	M. Zhang; M. De Respinis; H. Frei, Nat Chem 6 (2014) 362-367.
[69]	P. Ruetschi; P. Delahay, The Journal of Chemical Physics 23 (1955) 556-560.
[70]	C.G. Morales-Guio; L. Liardet; X. Hu, J Am Chem Soc 138 (2016) 8946-8957.
[71]	J.O.M. Bockris; T. Otagawa, Journal of The Electrochemical Society 131 (1984) 290.
[72]	J. Suntivich; K.J. May; H.A. Gasteiger; J.B. Goodenough; Y. Shao-Horn, Science 334 (2011) 1383-1385.
[73]	I. Yamada; A. Takamatsu; K. Asai; T. Shirakawa; H. Ohzuku; A. Seno; T. Uchimura; H. Fujii; S. Kawaguchi; K. Wada; H. Ikeno; S. Yagi, The Journal of Physical Chemistry C 122 (2018) 27885-27892.
[74]	A. Grimaud; O. Diaz-Morales; B. Han; W.T. Hong; Y.L. Lee; L. Giordano; K.A. Stoerzinger; M.T.M. Koper; Y. Shao-Horn, Nat Chem 9 (2017) 457-465.
[75]	S. Lee; K. Banjac; M. Lingenfelder; X. Hu, Angew Chem Int Ed Engl 58 (2019) 10295-10299.
[76]	J.T. Mefford; X. Rong; A.M. Abakumov; W.G. Hardin; S. Dai; A.M. Kolpak; K.P. Johnston; K.J. Stevenson, Nat Commun 7 (2016) 11053.
[77]	Z.-F. Huang; J. Song; Y. Du; S. Xi; S. Dou; J.M.V. Nsanzimana; C. Wang; Z.J. Xu; X. Wang, Nature Energy 4 (2019) 329-338.
[78]	A. Moysiadou; S. Lee; C.S. Hsu; H.M. Chen; X. Hu, J Am Chem Soc 142 (2020) 11901-11914.
[79]	C. Wang; P. Zhai; M. Xia; Y. Wu; B. Zhang; Z. Li; L. Ran; J. Gao; X. Zhang; Z. Fan; L. Sun; J. Hou, Angew Chem Int Ed Engl 60 (2021) 27126-27134.
[80]	F. Song; L. Bai; A. Moysiadou; S. Lee; C. Hu; L. Liardet; X. Hu, J Am Chem Soc 140 (2018) 7748-7759.
[81]	I.C. Man; H.Y. Su; F. Calle-Vallejo; H.A. Hansen; J.I. Martinez; N.G. Inoglu; J. Kitchin; T.F. Jaramillo; J.K. Noerskov; J. Rossmeisl, ChemCatChem 3 (2011) 1159-1165.
[82]	H. Wendt; E.V. Spinace; A. Oliveira Neto; M. Linardi, Quimica Nova 28 (2005) 1066-1075.
[83]	Y. Shi; B. Zhang, Chem Soc Rev 45 (2016) 1529-1541.
[84]	L. Zhang; Y. Qi; L. Sun; G. Chen; L. Wang; M. Zhang; D. Zeng; Y. Chen; X. Wang; K. Xu, Applied Surface Science 512 (2020) 145715.
[85]	Z.Y. Yu; Y. Duan; X.Y. Feng; X. Yu; M.R. Gao; S.H. Yu, Adv Mater 33 (2021) e2007100.
[86]	S. Anantharaj; S. Noda; V.R. Jothi; S. Yi; M. Driess; P.W. Menezes, Angew Chem Int Ed Engl 60 (2021) 18981-19006.
[87]	C. Wei; R.R. Rao; J. Peng; B. Huang; I.E.L. Stephens; M. Risch; Z.J. Xu; Y. Shao-Horn, Adv Mater 31 (2019) e1806296.
[88]	C. Wei; Z.J. Xu, The comprehensive understanding of as an evaluation parameter for electrochemical water splitting. Wiley Online Library: 2018; Vol. 2, p 1800168.
[89]	S. Anantharaj; S.R. Ede; K. Karthick; S. Sam Sankar; K. Sangeetha; P.E. Karthik; S. Kundu, Energy & Environmental Science 11 (2018) 744-771.
[90]	X. Zou; Y. Liu; G.-D. Li; Y. Wu; D.-P. Liu; W. Li; H.-W. Li; D. Wang; Y. Zhang; X. Zou, Advanced Materials 29 (2017).
[91]	S. Anantharaj; V. Aravindan, Advanced Energy Materials 10 (2019).
[92]	S. Xue; Z. Liu; C. Ma; H.-M. Cheng; W. Ren, Science Bulletin 65 (2020) 123-130.
[93]	S. Anantharaj; S. Noda, Small 16 (2020) e1905779.
[94]	Y. Jiao; Y. Zheng; M. Jaroniec; S.Z. Qiao, Chem Soc Rev 44 (2015) 2060-2086.
[95]	S. Anantharaj; P. Karthik; S. Kundu, Catalysis Science & Technology 7 (2017) 882-893.
[96]	K. Karthick; S. Anantharaj; P.E. Karthik; B. Subramanian; S. Kundu, Inorganic chemistry 56 (2017) 6734-6745.
[97]	A. Holewinski; S. Linic, Journal of The Electrochemical Society 159 (2012) H864.
[98]	C.G. Morales-Guio; L.A. Stern; X. Hu, Chem Soc Rev 43 (2014) 6555-6569.
[99]	Y. Peng; S. Chen, Green Energy Environ. 3 (2018) 335-351.
[100]	S. Anantharaj; K. Karthick; S. Kundu, Materials Today Energy 6 (2017) 1-26.
[101]	S. Anantharaj; S. Kundu, ACS Energy Letters 4 (2019) 1260-1264.
[102]	S. Anantharaj; P.E. Karthik; S. Noda, Angew Chem Int Ed Engl 60 (2021) 23051-23067.
[103]	S. Anantharaj; S.R. Ede; K. Sakthikumar; K. Karthick; S. Mishra; S. Kundu, ACS Catalysis 6 (2016) 8069-8097.
[104]	S. Anantharaj; P.E. Karthik; S. Kundu, Catalysis Science & Technology 7 (2017) 882-893.
[105]	J. Dong; F.-Q. Zhang; Y. Yang; Y.-B. Zhang; H. He; X. Huang; X. Fan; X.-M. Zhang, Applied Catalysis B: Environmental 243 (2019) 693-702.
[106]	Y. Wu; G.-D. Li; Y. Liu; L. Yang; X. Lian; T. Asefa; X. Zou, Advanced Functional Materials 26 (2016) 4839-4847.
[107]	J.-H. Wang; Z. Cheng; J.-L. Bredas; M. Liu, The Journal of chemical physics 127 (2007) 214705.
[108]	S. Anantharaj; S. Kundu; S. Noda, Journal of Materials Chemistry A 8 (2020) 4174-4192.
[109]	J. Chang; Y. Xiao; M. Xiao; J. Ge; C. Liu; W. Xing, ACS Catalysis 5 (2015) 6874-6878.
[110]	S. Anantharaj; H. Sugime; S. Noda, Chemical Engineering Journal 408 (2021) 127275.
[111]	J.-W. Zhang; X.-W. Lv; T.-Z. Ren; Z. Wang; T.J. Bandosz; Z.-Y. Yuan, Green Energy Environ. 7 (2022) 1024-1032.
[112]	S. Anantharaj; S. Kundu; S. Noda, Nano Energy 80 (2021) 105514.
[113]	S. Jin, ACS Energy Letters 2 (2017) 1937-1938.
[114]	S. Zhao; Y. Yang; Z. Tang, Angew Chem Int Ed Engl 61 (2022) e202110186.
[115]	Y. Wu; Y. Li; M. Yuan; H. Hao; X. San; Z. Lv; L. Xu; B. Wei, Chemical Engineering Journal 427 (2022) 131944.
[116]	Y. Xie; Y. Sun; H. Tao; X. Wang; J. Wu; K. Ma; L. Wang; Z. Kang; Y. Zhang, Advanced Functional Materials 32 (2022) 2111777.
[117]	F. Dionigi; P. Strasser, Advanced Energy Materials 6 (2016) 1600621.
[118]	Q. Ma; C. Hu; K. Liu; S.-F. Hung; D. Ou; H.M. Chen; G. Fu; N. Zheng, Nano Energy 41 (2017) 148-153.
[119]	X. Wu; X. Song; H. Tan; Y. Kang; Z. Zhao; S. Jin; X. Chang, Materials Today Energy 26 (2022) 101008.
[120]	M. Zheng; J. Du; B. Hou; C.-L. Xu, ACS Applied Materials & Interfaces 9 (2017) 26066-26076.
[121]	Y. Zhou; S. Xi; X. Yang; H. Wu, Journal of Solid State Chemistry 270 (2019) 398-406.
[122]	W. Zhang; D. Li; L. Zhang; X. She; D. Yang, Journal of Energy Chemistry 39 (2019) 39-53.
[123]	Y.L. Wang; X.Q. Wei; M.B. Li; P.Y. Hou; X.J. Xu, Applied Surface Science 436 (2018) 42-49.
[124]	R. Zhang; L. Cheng; Z. Wang; F. Kong; Y. Tsegazab; W. Lv; W. Wang, Applied Surface Science 526 (2020) 146753.
[125]	Z. Yan; H. Liu; Z. Hao; M. Yu; X. Chen; J. Chen, Chemical Science 11 (2020) 10614-10625.
[126]	J. Wang; X. Yue; Y. Yang; S. Sirisomboonchai; P. Wang; X. Ma; A. Abudula; G. Guan, Journal of Alloys and Compounds 819 (2020) 153346.
[127]	P. Ganesan; A. Sivanantham; S. Shanmugam, Journal of Materials Chemistry A 4 (2016) 16394-16402.
[128]	C.S. Rout; S. Mondal; R. Samal; A.S. Gangan; S.K. Nayak; B. Chakraborty, Applied Surface Science 497 (2019) 143789.
[129]	B. Li; Z. Li; F. He; Q. Pang; P. Shen, International Journal of Hydrogen Energy 44 (2019) 30806-30819.
[130]	W. Zhou; J. Zhao; J. Guan; M. Wu; G.R. Li, ACS Omega 4 (2019) 20244-20251.
[131]	F. Wu; X. Guo; G. Hao; Y. Hu; W. Jiang, Advanced Materials Interfaces 6 (2019) 1900788.
[132]	H. Liu; X. Ma; Y. Rao; Y. Liu; J. Liu; L. Wang; M. Wu, ACS Appl Mater Interfaces 10 (2018) 10890-10897.
[133]	C. Yang; M.Y. Gao; Q.B. Zhang; J.R. Zeng; X.T. Li; A.P. Abbott, Nano Energy 36 (2017) 85-94.
[134]	X. Du; Z. Yang; Y. Li; Y. Gong; M. Zhao, Journal of Materials Chemistry A 6 (2018) 6938-6946.
[135]	W. Zhu; X. Yue; W. Zhang; S. Yu; Y. Zhang; J. Wang; J. Wang, Chemical communications 52 (2016) 1486-1489.
[136]	M. Zheng; J. Du; B. Hou; C.L. Xu, ACS Appl Mater Interfaces 9 (2017) 26066-26076.
[137]	M. Shao; P. Wang; Y. Wang; B. Wang; Y. Wang; J. Xu, Green Energy Environ. 6 (2021) 858-865.
[138]	J. Zhang; T. Wang; D. Pohl; B. Rellinghaus; R. Dong; S. Liu; X. Zhuang; X. Feng, Angew Chem Int Ed Engl 55 (2016) 6702-6707.
[139]	Y. Yang; K. Zhang; H. Lin; X. Li; H.C. Chan; L. Yang; Q. Gao, ACS Catalysis 7 (2017) 2357-2366.
[140]	X. Meng; L. Yu; C. Ma; B. Nan; R. Si; Y. Tu; J. Deng; D. Deng; X. Bao, Nano Energy 61 (2019) 611-616.
[141]	T. An; Y. Wang; J. Tang; W. Wei; X. Cui; A.M. Alenizi; L. Zhang; G. Zheng, Journal of Materials Chemistry A 4 (2016) 13439-13443.
[142]	J. Cao; J. Zhou; Y. Zhang; Y. Wang; X. Liu, ACS Appl Mater Interfaces 10 (2018) 1752-1760.
[143]	Y. Yang; H. Yao; Z. Yu; S.M. Islam; H. He; M. Yuan; Y. Yue; K. Xu; W. Hao; G. Sun, Journal of the American Chemical Society 141 (2019) 10417-10430.
[144]	W. He; R. Zhang; D. Cao; Y. Li; J. Zhang; Q. Hao; H. Liu; J. Zhao; H.L. Xin, Small 19 (2023) e2205719.
[145]	X. Ji; Y. Lin; J. Zeng; Z. Ren; Z. Lin; Y. Mu; Y. Qiu; J. Yu, Nature Communications 12 (2021).
[146]	Q. Xu; H. Jiang; H. Zhang; Y. Hu; C. Li, Applied Catalysis B: Environmental 242 (2019) 60-66.
[147]	J. Zhang; Q. Xu; J. Wang; Y. Hu; H. Jiang; C. Li, Science China Materials 66 (2022) 634-640.
[148]	J. Perez-Ramirez; N. Lopez, Nature Catalysis 2 (2019) 971-976.
[149]	Y. Yang; H. Yao; Z. Yu; S.M. Islam; H. He; M. Yuan; Y. Yue; K. Xu; W. Hao; G. Sun; H. Li; S. Ma; P. Zapol; M.G. Kanatzidis, J Am Chem Soc 141 (2019) 10417-10430.
[150]	N. Cheng; Q. Liu; A.M. Asiri; W. Xing; X. Sun, Journal of Materials Chemistry A 3 (2015) 23207-23212.
[151]	D. Shao; P. Li; R. Zhang; C. Zhao; D. Wang; C. Zhao, International Journal of Hydrogen Energy 44 (2019) 2664-2674.
[152]	W. Zhang; Q. Jia; H. Liang; L. Cui; D. Wei; J. Liu, Chemical Engineering Journal 396 (2020) 125315.
[153]	L. Wang; Y. Li; Q. Sun; Q. Qiang; Y. Shen; Y. Ma; Z. Wang; C. Zhao, ChemCatChem 11 (2019) 2011-2016.
[154]	H. Liu; Z. Guo; J. Lian, Journal of Solid State Chemistry 293 (2021) 121776.
[155]	J.-F. Qin; M. Yang; S. Hou; B. Dong; T.-S. Chen; X. Ma; J.-Y. Xie; Y.-N. Zhou; J. Nan; Y.-M. Chai, Applied Surface Science 502 (2020) 144172.
[156]	G. Li; X. Cui; B. Song; H. Ouyang; K. Wang; Y. Sun; Y. Wang, Chemical Engineering Journal 388 (2020) 124319.
[157]	J.X. Feng; J.Q. Wu; Y.X. Tong; G.R. Li, J Am Chem Soc 140 (2018) 610-617.
[158]	Y. Ding; X. Du; X. Zhang, ChemCatChem 13 (2021) 1824-1833.
[159]	L. Ma; K. Zhang; S. Wang; L. Gao; Y. Sun; Q. Liu; J. Guo; X. Zhang, Applied Surface Science 489 (2019) 815-823.
[160]	Y. Qu; M. Yang; J. Chai; Z. Tang; M. Shao; C.T. Kwok; M. Yang; Z. Wang; D. Chua; S. Wang, ACS applied materials & interfaces 9 (2017) 5959-5967.
[161]	Y. Qu; M. Shao; Y. Shao; M. Yang; J. Xu; C.T. Kwok; X. Shi; Z. Lu; H. Pan, Journal of Materials Chemistry A 5 (2017) 15080-15086.
[162]	J. Zhou; L. Yu; Q. Zhu; C. Huang; Y. Yu, Journal of Materials Chemistry A 7 (2019) 18118-18125.
[163]	J. Hu; C. Zhang; X. Meng; H. Lin; C. Hu; X. Long; S. Yang, Journal of Materials Chemistry A 5 (2017) 5995-6012.
[164]	Z. Cui; Y. Ge; H. Chu; R. Baines; P. Dong; J. Tang; Y. Yang; P.M. Ajayan; M. Ye; J. Shen, Journal of Materials Chemistry A 5 (2017) 1595-1602.
[165]	X. Zhong; J. Tang; J. Wang; M. Shao; J. Chai; S. Wang; M. Yang; Y. Yang; N. Wang; S. Wang; B. Xu; H. Pan, Electrochimica Acta 269 (2018) 55-61.
[166]	T. Kou; T. Smart; B. Yao; I. Chen; D. Thota; Y. Ping; Y. Li, Advanced Energy Materials 8 (2018).
[167]	W. He; L. Han; Q. Hao; X. Zheng; Y. Li; J. Zhang; C. Liu; H. Liu; H.L. Xin, ACS Energy Letters 4 (2019) 2905-2912.
[168]	X. Du; Q. Wang; X. Zhang; Z. Wang, International Journal of Hydrogen Energy 47 (2022) 25595-25607.
[169]	Y. Ding; H. Li; Y. Hou, International Journal of Hydrogen Energy 43 (2018) 19002-19009.
[170]	Y. Zhao; J. You; L. Wang; W. Bao; R. Yao, International Journal of Hydrogen Energy 46 (2021) 39146-39182.
[171]	S.-S. Lu; L.-M. Zhang; Y.-W. Dong; J.-Q. Zhang; X.-T. Yan; D.-F. Sun; X. Shang; J.-Q. Chi; Y.-M. Chai; B. Dong, Journal of Materials Chemistry A 7 (2019) 16859-16866.
[172]	L. Zhang; P.F. Liu; Y.H. Li; C.W. Wang; M.Y. Zu; H.Q. Fu; X.H. Yang; H.G. Yang, ACS Catalysis 8 (2018) 5200-5205.
[173]	D. Voiry; J. Yang; M. Chhowalla, Adv Mater 28 (2016) 6197-6206.
[174]	L. Ye; Y. Du; Y. Zhao; L. Zhao, ACS Applied Nano Materials 3 (2020) 8372-8381.
[175]	Q. Liu; L. Xie; Z. Liu; G. Du; A.M. Asiri; X. Sun, Chemical communications 53 (2017) 12446-12449.
[176]	Q. Che; Q. Li; X. Chen; Y. Tan; X. Xu, Applied Catalysis B: Environmental 263 (2020) 118338.
[177]	S. Song; Y. Wang; W. Li; P. Tian; S. Zhou; H. Gao; X. Tian; J. Zang, Electrochimica Acta 332 (2020) 135454.
[178]	Y. Zhu; H. Yang; K. Lan; K. Iqbal; Y. Liu; P. Ma; Z. Zhao; S. Luo; Y. Luo; J. Ma, Nanoscale 11 (2019) 2355-2365.
[179]	J. Li; G. Zheng, Adv Sci (Weinh) 4 (2017) 1600380.
[180]	M.S. Faber; R. Dziedzic; M.A. Lukowski; N.S. Kaiser; Q. Ding; S. Jin, Journal of the American Chemical Society 136 (2014) 10053-10061.
[181]	Y. Wang; T. Wang; P. Da; M. Xu; H. Wu; G. Zheng, Advanced materials 25 (2013) 5177-5195.
[182]	J. Li; P.K. Shen; Z. Tian, International Journal of Hydrogen Energy 42 (2017) 7136-7142.
[183]	B. Li; Z. Li; Q. Pang; J.Z. Zhang, Chemical Engineering Journal 401 (2020) 126045.
[184]	J. Li; P. Xu; R. Zhou; R. Li; L. Qiu; S.P. Jiang; D. Yuan, Electrochimica Acta 299 (2019) 152-162.
[185]	H. Xu; Y. Jiao; S. Li; H. Meng; J. Wu; X. Shi; Z. Du; R. Wang; G. Tian, International Journal of Hydrogen Energy 45 (2020) 13149-13162.
[186]	R. Subbaraman; D. Tripkovic; D. Strmcnik; K.C. Chang; M. Uchimura; A.P. Paulikas; V. Stamenkovic; N.M. Markovic, Science 334 (2011) 1256-1260.
[187]	L. Cong; H. Xie; J. Li, Advanced Energy Materials 7 (2017) 1601906.
[188]	L. Zeng; K. Sun; Z. Yang; S. Xie; Y. Chen; Z. Liu; Y. Liu; J. Zhao; Y. Liu; C. Liu, Journal of Materials Chemistry A 6 (2018) 4485-4493.
[189]	X. Nie; X. Kong; D. Selvakumaran; L. Lou; J. Shi; T. Zhu; S. Liang; G. Cao; A. Pan, ACS Appl Mater Interfaces 10 (2018) 36018-36027.
[190]	H.-C. Tsai; B. Vedhanarayanan; T.-W. Lin, ACS Applied Energy Materials 2 (2019) 3708-3716.
[191]	Y. Wu; Y. Liu; G.-D. Li; X. Zou; X. Lian; D. Wang; L. Sun; T. Asefa; X. Zou, Nano Energy 35 (2017) 161-170.
[192]	J. Lin; H. Wang; X. Zheng; Y. Du; C. Zhao; J. Qi; J. Cao; W. Fei; J. Feng, Journal of Power Sources 401 (2018) 329-335.
[193]	G. Liu; Y. Wu; R. Yao; F. Zhao; Q. Zhao; J. Li, Green Energy Environ. 6 (2021) 496-505.
[194]	W. Zhou; X.-J. Wu; X. Cao; X. Huang; C. Tan; J. Tian; H. Liu; J. Wang; H. Zhang, Energy & Environmental Science 6 (2013) 2921-2924.
[195]	Y. Xu; C. Wang; Y. Huang; J. Fu, Nano Energy 80 (2021) 105545.
[196]	S. Hao; Q. Cao; L. Yang; R. Che, Journal of Alloys and Compounds 827 (2020) 154163.
[197]	J. He; B. Hu; Y. Zhao, Advanced Functional Materials 26 (2016) 5998-6004.
[198]	L.L. Wu; Y.X. Yang; X.H. Chen; J. Luo; H.C. Fu; L. Shen; H.Q. Luo; N.B. Li, Chemical Communications 56 (2020) 12339-12342.
[199]	A. Ali; P.K. Shen, Electrochemical Energy Reviews 3 (2020) 370-394.
[200]	L. Zhang; J.-S. Hu; X.-H. Huang; J. Song; S.-Y. Lu, Nano Energy 48 (2018) 489-499.
[201]	X. Wei; Y. Li; W. Xu; K. Zhang; J. Yin; S. Shi; J. Wei; F. Di; J. Guo; C. Wang; C. Chu; N. Sui; B. Chen; Y. Zhang; H. Hao; X. Zhang; J. Zhao; H. Zhou; S. Wang, R Soc Open Sci 4 (2017) 171409.
[202]	D. Zhang; H. Mou; F. Lu; C. Song; D. Wang, Applied Catalysis B: Environmental 254 (2019) 471-478.
[203]	R.D. Smith; M.S. Prevot; R.D. Fagan; Z. Zhang; P.A. Sedach; M.K.J. Siu; S. Trudel; C.P. Berlinguette, Science 340 (2013) 60-63.
[204]	H. Zhou; F. Yu; J. Sun; R. He; S. Chen; C.W. Chu; Z. Ren, Proc Natl Acad Sci U S A 114 (2017) 5607-5611.
[205]	L. Zhu; H. Lin; Y. Li; F. Liao; Y. Lifshitz; M. Sheng; S.T. Lee; M. Shao, Nat Commun 7 (2016) 12272.
[206]	Y. Niu; W. Li; X. Wu; B. Feng; Y. Yu; W. Hu; C.M. Li, Journal of Materials Chemistry A 7 (2019) 10534-10542.
[207]	X. Wang; W. Zhang; J. Zhang; Z. Wu, ChemElectroChem 6 (2019) 4550-4559.
[208]	J. Jian; L. Yuan; H. Qi; X. Sun; L. Zhang; H. Li; H. Yuan; S. Feng, ACS Applied Materials & Interfaces 10 (2018) 40568-40576.
[209]	L. Trotochaud; S.L. Young; J.K. Ranney; S.W. Boettcher, Journal of the American Chemical Society 136 (2014) 6744-6753.
[210]	M.S. Burke; L.J. Enman; A.S. Batchellor; S. Zou; S.W. Boettcher, Chemistry of Materials 27 (2015) 7549-7558.
[211]	N. Yang; C. Tang; K. Wang; G. Du; A.M. Asiri; X. Sun, Nano Research 9 (2016) 3346-3354.
[212]	H. Qin; B. Zhang; Y. Pan; X. Wang; L. Diao; J. Chen; J. Wu; E. Liu; J. Sha; L. Ma; N. Zhao, Journal of Catalysis 381 (2020) 493-500.
[213]	W. Gao; F. Ma; C. Wang; D. Wen, Journal of Power Sources 450 (2020) 227654.
[214]	W. Chen; Y. Liu; Y. Li; J. Sun; Y. Qiu; C. Liu; G. Zhou; Y. Cui, Nano Lett 16 (2016) 7588-7596.
[215]	C. Tang; N. Cheng; Z. Pu; W. Xing; X. Sun, Angew Chem Int Ed Engl 54 (2015) 9351-9355.
[216]	Q. Zhang; Y. Wang; Y. Wang; A.M. Al-Enizi; A.A. Elzatahry; G. Zheng, Journal of Materials Chemistry A 4 (2016) 5713-5718.
[217]	X. Du; P. Che; Y. Wang; C. Yuan; X. Zhang, International Journal of Hydrogen Energy 44 (2019) 22955-22961.
[218]	X. Jia; Y. Zhao; G. Chen; L. Shang; R. Shi; X. Kang; G.I. Waterhouse; L.Z. Wu; C.H. Tung; T. Zhang, Advanced Energy Materials 6 (2016) 1502585.
[219]	M. Yao; B. Sun; L. He; N. Wang; W. Hu; S. Komarneni, ACS Sustainable Chemistry & Engineering 7 (2019) 5430-5439.
[220]	A. Taqieddin; R. Nazari; L. Rajic; A. Alshawabkeh, J Electrochem Soc 164 (2017) E448-E459.
[221]	C. Gabrielli; F. Huet; R. Nogueira, Electrochimica Acta 50 (2005) 3726-3736.
[222]	G.B. Darband; M. Aliofkhazraei; S. Shanmugam, Renewable and Sustainable Energy Reviews 114 (2019).
[223]	M. Liu; S. Wang; Z. Wei; Y. Song; L. Jiang, Advanced Materials 21 (2009) 665-669.
[224]	L. Wen; Y. Tian; L. Jiang, Angew Chem Int Ed Engl 54 (2015) 3387-3399.
[225]	Z. Lu; W. Zhu; X. Yu; H. Zhang; Y. Li; X. Sun; X. Wang; H. Wang; J. Wang; J. Luo; X. Lei; L. Jiang, Adv Mater 26 (2014) 2683-2687, 2615.
[226]	M. Guo; A. Qayum; S. Dong; X. Jiao; D. Chen; T. Wang, Journal of Materials Chemistry A 8 (2020) 9239-9247.
[227]	D. Zhang; J. Li; J. Luo; P. Xu; L. Wei; D. Zhou; W. Xu; D. Yuan, Nanotechnology 29 (2018) 245402.
[228]	G. Janani; H. Choi; S. Surendran; U. Sim, MRS Bulletin 45 (2020) 539-547.
[229]	J.J. Duan; R.L. Zhang; J.J. Feng; L. Zhang; Q.L. Zhang; A.J. Wang, J Colloid Interface Sci 581 (2021) 774-782.
[230]	Q. Liu; J. Huang; Y. Zhao; L. Cao; K. Li; N. Zhang; D. Yang; L. Feng; L. Feng, Nanoscale 11 (2019) 8855-8863.
[231]	Z. Lu; Y. Li; X. Lei; J. Liu; X. Sun, Materials Horizons 2 (2015) 294-298.
[232]	L. Jiang; N. Yang; C. Yang; X. Zhu; Y. Jiang; X. Shen; C. Li; Q. Sun, Applied Catalysis B: Environmental 269 (2020) 118780.
[233]	Y. Guo; Z. Wang; L. Zhang; X. Shen; F. Liu, Physical Chemistry Chemical Physics 18 (2016) 14449-14453.
[234]	A.P. Gaur; S. Sahoo; M. Ahmadi; S.P. Dash; M.J. Guinel; R.S. Katiyar, Nano Lett 14 (2014) 4314-4321.
[235]	Y. Liu; L.-M. Pan; H. Liu; T. Chen; S. Yin; M. Liu, International Journal of Hydrogen Energy 44 (2019) 1352-1358.
[236]	J.A. Koza; S. Muhlenhoff; P. Zabinski; P.A. Nikrityuk; K. Eckert; M. Uhlemann; A. Gebert; T. Weier; L. Schultz; S. Odenbach, Electrochimica Acta 56 (2011) 2665-2675.
[237]	H. Matsushima; T. Iida; Y. Fukunaka, Electrochimica Acta 100 (2013) 261-264.
[238]	J. Yan; Y. Wang; Y. Zhang; S. Xia; J. Yu; B. Ding, Advanced Materials 33 (2021) 2007525.
[239]	M. Wang; Z. Wang; Z. Guo, International Journal of Hydrogen Energy 34 (2009) 5311-5317.
[240]	T. Kou; S. Wang; Y. Li, ACS Materials Letters 3 (2021) 224-234.
[241]	Y. Liu; X. Liang; L. Gu; Y. Zhang; G.D. Li; X. Zou; J.S. Chen, Nat Commun 9 (2018) 2609.
[242]	X. Zhao; H. Ren; L. Luo, Langmuir 35 (2019) 5392-5408.
[243]	B. Han; K.A. Stoerzinger; V. Tileli; A.D. Gamalski; E.A. Stach; Y. Shao-Horn, Nat Mater 16 (2017) 121-126.
[244]	Y. Luo; Z. Zhang; M. Chhowalla; B. Liu, Adv Mater 34 (2022) e2108133.
[245]	Q. Wen; Y. Zhao; Y. Liu; H. Li; T. Zhai, Small 18 (2022) e2104513.
[246]	S.-W. Wu; S.-Q. Liu; X.-H. Tan; W.-Y. Zhang; K. Cadien; Z. Li, Chemical Engineering Journal 442 (2022) 136105.
[247]	C. Liang; P. Zou; A. Nairan; Y. Zhang; J. Liu; K. Liu; S. Hu; F. Kang; H.J. Fan; C. Yang, Energy & Environmental Science 13 (2020) 86-95.
[248]	Y. Kuang; M.J. Kenney; Y. Meng; W.H. Hung; Y. Liu; J.E. Huang; R. Prasanna; P. Li; Y. Li; L. Wang; M.C. Lin; M.D. Mcgehee; X. Sun; H. Dai, Proc Natl Acad Sci U S A 116 (2019) 6624-6629.
[249]	T. Shinagawa; M.T. Ng; K. Takanabe, Angew Chem Int Ed Engl 56 (2017) 5061-5065.

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Recent advances and future prospects on Ni₃S₂-Based electrocatalysts for efficient alkaline water electrolysis

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Recent advances and future prospects on Ni3S2-Based electrocatalysts for efficient alkaline water electrolysis

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Recent advances and future prospects on Ni₃S₂-Based electrocatalysts for efficient alkaline water electrolysis