Volume 2 Issue 4
December  2023
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Xinyu Li, Yingjie Liu, Yanhui Feng, Yunwei Tong, Zhenbo Qin, Zhong Wu, Yida Deng, Wenbin Hu. Research prospects of graphene-based catalyst for seawater electrolysis[J]. Materials Futures, 2023, 2(4): 042104. doi: 10.1088/2752-5724/acf2fd
Citation: Xinyu Li, Yingjie Liu, Yanhui Feng, Yunwei Tong, Zhenbo Qin, Zhong Wu, Yida Deng, Wenbin Hu. Research prospects of graphene-based catalyst for seawater electrolysis[J]. Materials Futures, 2023, 2(4): 042104. doi: 10.1088/2752-5724/acf2fd
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Topical Review •
OPEN ACCESS

Research prospects of graphene-based catalyst for seawater electrolysis

© 2023 The Author(s). Published by IOP Publishing Ltd on behalf of the Songshan Lake Materials Laboratory
Materials Futures, Volume 2, Number 4
  • Received Date: 2023-06-27
  • Accepted Date: 2023-08-17
  • Publish Date: 2023-09-19
doi: 10.1088/2752-5724/acf2fd

  • 1 Key Laboratory of Advanced Ceramics and Machining Technology of Ministry of Education Tianjin University, Tianjin 300072, People’s Republic of China

  • 2 Key Laboratory of Composite and Functional Materials School of Material Science and Engineering, Tianjin University, Tianjin 300072, People’s Republic of China

  • 3 State Key Laboratory of Marine Resource Utilization in South China Sea, School of Materials Science and Engineering, Hainan University, Haikou 570228, People’s Republic of China

  • 4 Joint School of National University of Singapore and Tianjin University International Campus of Tianjin University, Binhai New City, Fuzhou 350207, People’s Republic of China

Funds:

We gratefully acknowledge the financial support from Yunnan Precious Metals Laboratory Science and Technology Project (Grant No. YPML-2023050274) and National Natural Science Foundation of China (Grant Nos. 52231008, 52171078).

    Abstract
  • Seawater has obvious resource reserve advantages compared to fresh water, and so the huge potential advantages for large-scale electrolysis of hydrogen production has been paid more attention to; but at the same time, electrolysis of seawater requires more stable and active catalysts to deal with seawater corrosion problems. Graphene-based materials are very suitable as composite supports for catalysts due to their high electrical conductivity, specific surface area, and porosity. Therefore, the review introduces the problems faced by seawater electrolysis for hydrogen production and the various catalysts performance. Among them, the advantages of catalysis of graphene-based catalysts and the methods of enhancement the catalytic performance of graphene are emphasized. Finally, the development direction of composite catalysts is prospected, hoping to provide guidance for the preparation of more efficient electrocatalysts for seawater electrolysis.
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  • [1]
    Oh S, Cho T, Kim M, Lim J, Eom K, Kim D, Cho E and Kwon H 2017 Fabrication of Mg–Ni–Sn alloys for fast hydrogen generation in seawater Int. J. Hydrog. Energy 42 7761–9
    [2]
    Kuang Y et al 2019 Solar-driven, highly sustained splitting of seawater into hydrogen and oxygen fuels Proc. Natl Acad. Sci. USA 116 6624–9
    [3]
    Ahmed A, Al-Amin A Q, Ambrose A F and Saidur R 2016 Hydrogen fuel and transport system: a sustainable and environmental future Int. J. Hydrog. Energy 41 1369–80
    [4]
    Choi P 2004 A simple model for solid polymer electrolyte (SPE) water electrolysis Solid State Ion. 175 535–9
    [5]
    Trasatti S 1999 Water electrolysis: who first? J. Electroanal. Chem. 476 90–91
    [6]
    Abdalla A M, Hossain S, Nisfindy O B, Azad A T, Dawood M and Azad A K 2018 Hydrogen production, storage, transportation and key challenges with applications: a review Energy Convers. Manage. 165 602–27
    [7]
    Cortright R, Davda R and Dumesic J 2002 Hydrogen from catalytic reforming of biomass-derived hydrocarbons in liquid water Nature 418 964–7
    [8]
    Wang B, Li Y and Ren N 2013 Biohydrogen from molasses with ethanol-type fermentation: effect of hydraulic retention time Int. J. Hydrog. Energy 38 4361–7
    [9]
    Wen-Hui Y, Xiao-Chen L I U and Li L I 2013 Improving photocatalytic performance for hydrogen generation over co-doped ZnIn2S4 under visible light Acta Phys. - Chim. Sin. 29 151–6
    [10]
    Licht S et al 2001 Over 18% solar energy conversion to generation of hydrogen fuel; theory and experiment for efficient solar water splitting Int. J. Hydrog. Energy 26 653–9
    [11]
    Luo Y, Zhang Z, Chhowalla M and Liu B 2022 Recent advances in design of electrocatalysts for highcurrent-density water splitting Adv. Mater. 34 2108133
    [12]
    Esquius J R and Lifeng L 2023 High entropy materials as emerging electrocatalysts for hydrogen production through low-temperature water electrolysis Mater. Futures 2 022102
    [13]
    Yuan L, Weidong L, Han W and Siyu L 2021 Carbon dots enhance ruthenium nanoparticles for efficient hydrogen production in alkaline Acta Phys.-Chim. Sin. 37 169–80
    [14]
    Chae S-Y, Yadav J B, Kim K-J and Joo O-S 2011 Durability study of electrospray deposited Pt film electrode for hydrogen production in PV assisted water electrolysis system Int. J. Hydrog. Energy 36 3347–53
    [15]
    Juodkazytė J, Šebeka B, Savickaja I, Petrulevčiienė M, Butkutė S, Jasulaitienė V, Selskis A and Ramanauskas R 2019 Electrolytic splitting of saline water: durable nickel oxide anode for selective oxygen evolution Int. J. Hydrog. Energy 44 5929–39
    [16]
    Peñate B and García-Rodríguez L 2012 Current trends and future prospects in the design of seawater reverse osmosis desalination technology Desalination 284 1–8
    [17]
    Schallenberg-Rodríguez J, Veza J M and Blanco-Marigorta A 2014 Energy efficiency and desalination in the Canary Islands Renew. Sustain. Energy Rev. 40 741–8
    [18]
    Gao L, Yoshikawa S, Iseri Y, Fujimori S and Kanae S 2017 An economic assessment of the global potential for seawater desalination to 2050 Water 9 763
    [19]
    Jia X, Klemeˇs J, Varbanov P and Wan Alwi S 2019 Analyzing the energy consumption, GHG emission, and cost of seawater desalination in China Energies 12 463
    [20]
    Wittholz M K, O’Neill B K, Colby C B and Lewis D 2008 Estimating the cost of desalination plants using a cost database Desalination 229 10–20
    [21]
    Xiang X and Liu X 2022 Research on the economic and environmental impacts of China’s seawater desalination industry with different technologies in the macroeconomic system Desalination 533 115734
    [22]
    Dresp S, Dionigi F, Klingenhof M and Strasser P 2019 Direct electrolytic splitting of seawater: opportunities and challenges ACS Energy Lett. 4 933–42
    [23]
    Dionigi F, Reier T, Pawolek Z, Gliech M and Strasser P 2016 Design criteria, operating conditions, and nickel-iron hydroxide catalyst materials for selective seawater electrolysis ChemSusChem 9 962–72
    [24]
    Zhou G, Guo Z, Shan Y, Wu S, Zhang J, Yan K, Liu L, Chu P K and Wu X 2019 High-efficiency hydrogen evolution from seawater using hetero-structured T/Td phase ReS2 nanosheets with cationic vacancies Nano Energy 55 42–48
    [25]
    Lim T, Jung G Y, Kim J H, Park S O, Park J, Kim Y-T, Kang S J, Jeong H Y, Kwak S K and Joo S H 2020 Atomically dispersed Pt-N4 sites as efficient and selective electrocatalysts for the chlorine evolution reaction Nat. Commun. 11 412
    [26]
    Goryachev A, Etzi Coller Pascuzzi M, Carlà F, Weber T, Over H, Hensen E J M and Hofmann J P 2020 Electrochemical stability of RuO2(110)/Ru(0001) model electrodes in the oxygen and chlorine evolution reactions Electrochim. Acta 336 135713
    [27]
    Ko J S, Johnson J K, Johnson P I and Xia Z 2020 Decoupling oxygen and chlorine evolution reactions in seawater using iridium-based electrocatalysts ChemCatChem 12 4526–32
    [28]
    Ji X, Lin Y, Zeng J, Ren Z, Lin Z, Mu Y, Qiu Y and Yu J 2021 Graphene/MoS2/FeCoNi(OH)x and Graphene/MoS2/FeCoNiPx multilayer-stacked vertical nanosheets on carbon fibers for highly efficient overall water splitting Nat. Commun. 12 1380
    [29]
    Jiang S, Liu Y, Qiu H, Su C and Shao Z 2022 High selectivity electrocatalysts for oxygen evolution reaction and anti-chlorine corrosion strategies in seawater splitting Catalysts 12 261
    [30]
    Chen M, Kitiphatpiboon N, Feng C, Abudula A, Ma Y and Guan G 2023 Recent progress in transition-metal-oxide-based electrocatalysts for the oxygen evolution reaction in natural seawater splitting: a critical review eScience 3 100111
    [31]
    Wang H, Weng C-C, Ren J-T and Yuan Z-Y 2021 An overview and recent advances in electrocatalysts for direct seawater splitting Front. Chem. Sci. Eng. 15 1–19
    [32]
    Gao S, Li G-D, Liu Y, Chen H, Feng L-L, Wang Y, Yang M, Wang D, Wang S and Zou X 2015 Electrocatalytic H2 production from seawater over Co, N-codoped nanocarbons Nanoscale 7 2306–16
    [33]
    Sarno M, Sannino D, Leone C and Ciambelli P 2012 Evaluating the effects of operating conditions on the quantity, quality and catalyzed growth mechanisms of CNTs J. Mol. Catal. A 357 26–38
    [34]
    Zhuang L, Li S, Li J, Wang K, Guan Z, Liang C and Xu Z 2022 Recent advances on hydrogen evolution and oxygen evolution catalysts for direct seawater splitting Coatings 12 659
    [35]
    Zou X and Zhang Y 2015 Noble metal-free hydrogen evolution catalysts for water splitting Chem. Soc. Rev. 44 5148–80
    [36]
    Niu X, Tang Q, He B and Yang P 2016 Robust and stable ruthenium alloy electrocatalysts for hydrogen evolution by seawater splitting Electrochim. Acta 208 180–7
    [37]
    Shi Y-C, Feng J-J, Lin X-X, Zhang L, Yuan J, Zhang Q-L and Wang A-J 2019 One-step hydrothermal synthesis of three-dimensional nitrogen-doped reduced graphene oxide hydrogels anchored PtPd alloyed nanoparticles for ethylene glycol oxidation and hydrogen evolution reactions Electrochim. Acta 293 504–13
    [38]
    Sarno M, Ponticorvo E and Scarpa D 2020 Active and stable graphene supporting trimetallic alloy-based electrocatalyst for hydrogen evolution by seawater splitting Electrochem. Commun. 111 106647
    [39]
    Li H, Tang Q, He B and Yang P 2016 Robust electrocatalysts from an alloyed Pt–Ru–M (M = Cr, Fe, Co, Ni, Mo)-decorated Ti mesh for hydrogen evolution by seawater splitting J. Mater. Chem. A 4 6513–20
    [40]
    Ma Y-Y, Wu C-X, Feng X-J, Tan H-Q, Yan L-K, Liu Y, Kang Z-H, Wang E-B and Li Y-G 2017 Highly efficient hydrogen evolution from seawater by a low-cost and stable CoMoP@C electrocatalyst superior to Pt/C Energy Environ. Sci. 10 788–98
    [41]
    Jin H, Liu X, Vasileff A, Jiao Y, Zhao Y, Zheng Y and Qiao S-Z 2018 Single-crystal nitrogen-rich two-dimensional Mo5N6 nanosheets for efficient and stable seawater splitting ACS Nano 12 12761–9
    [42]
    Chen I P, Hsiao C H, Huang J Y, Peng Y H and Chang C Y 2019 Highly efficient hydrogen evolution from seawater by biofunctionalized exfoliated MoS2 quantum dot aerogel electrocatalysts that is superior to Pt ACS Appl. Mater. Interfaces 11 14159–65
    [43]
    Lu X, Pan J, Lovell E, Tan T H, Ng Y H and Amal R 2018 A sea-change: manganese doped nickel/nickel oxide electrocatalysts for hydrogen generation from seawater Energy Environ. Sci. 11 1898–910
    [44]
    Zheng J 2017 Seawater splitting for high-efficiency hydrogen evolution by alloyed PtNix electrocatalysts Appl. Surf. Sci. 413 360–5
    [45]
    Liu T, Liu H, Wu X, Niu Y, Feng B, Li W, Hu W and Li C M 2018 Molybdenum carbide/phosphide hybrid nanoparticles embedded P, N co-doped carbon nanofibers for highly efficient hydrogen production in acidic, alkaline solution and seawater Electrochim. Acta 281 710–6
    [46]
    Wu X, Zhou S, Wang Z, Liu J, Pei W, Yang P, Zhao J and Qiu J 2019 Engineering multifunctional collaborative catalytic interface enabling efficient hydrogen evolution in all pH range and seawater Adv. Energy Mater. 9 1901333
    [47]
    Zhang Y, Li P, Yang X, Fa W and Ge S 2018 High-efficiency and stable alloyed nickel based electrodes for hydrogen evolution by seawater splitting J. Alloys Compd. 732 248–56
    [48]
    Ganesan P, Sivanantham A and Shanmugam S 2017 Nanostructured nickel-cobalt-titanium alloy grown on titanium substrate as efficient electrocatalyst for alkaline water electrolysis ACS Appl. Mater. Interfaces 9 12416–26
    [49]
    Miao J et al 2018 Polyoxometalate-derived hexagonal molybdenum nitrides (MXenes) supported by boron, nitrogen codoped carbon nanotubes for efficient electrochemical hydrogen evolution from seawater Adv. Funct. Mater. 29 1805893
    [50]
    Zheng J 2017 Binary platinum alloy electrodes for hydrogen and oxygen evolutions by seawater splitting Appl. Surf. Sci. 413 72–82
    [51]
    Song L J and Meng H M 2010 Effect of carbon content on Ni–Fe–C electrodes for hydrogen evolution reaction in seawater Int. J. Hydrog. Energy 35 10060–6
    [52]
    Golgovici F et al 2018 Ni–Mo alloy nanostructures as cathodic materials for hydrogen evolution reaction during seawater electrolysis Chem. Zvesti 72 1889–903
    [53]
    Zhang L, Xu Q, Niu J and Xia Z 2015 Role of lattice defects in catalytic activities of graphene clusters for fuel cells Phys. Chem. Chem. Phys. 17 16733–43
    [54]
    Zhang L et al 2018 Graphene defects trap atomic Ni species for hydrogen and oxygen evolution reactions Chem 4 285–97
    [55]
    Meyer J, Kisielowski C, Erni R, Rossell M D, Crommie M F and Zettl A 2008 Direct imaging of lattice atoms and topological defects in graphene membranes Nano Lett. 8 3582–6
    [56]
    Yin H, Dou Y, Chen S, Zhu Z, Liu P and Zhao H 2020 2D electrocatalysts for converting earth-abundant simple molecules into value-added commodity chemicals: recent progress and perspectives Adv. Mater. 32 e1904870
    [57]
    Zhang Y, Tan Y W, Stormer H L and Kim P 2005 Experimental observation of the quantum Hall effect and Berry’s phase in grapheme Nature 438 201–4
    [58]
    Novoselov K S, Geim A K, Morozov S V, Jiang D, Katsnelson M I, Grigorieva I V, Dubonos S V and Firsov A A 2005 Two-dimensional gas of massless Dirac fermions in grapheme Nature 438 197–200
    [59]
    Charlier J-C et al 2008 Electron and phonon properties of graphene: their relationship with carbon nanotubes Carbon Nanotubes vol 111, ed A Jorio, G Dresselhaus and M S Dresselhaus (springer) pp 673–709
    [60]
    Morozov S V, Novoselov K S, Katsnelson M I, Schedin F, Elias D C, Jaszczak J A and Geim A K 2008 Giant intrinsic carrier mobilities in graphene and its bilayer Phys. Rev. Lett. 100 016602
    [61]
    Rao C N, Sood A K, Subrahmanyam K S and Govindaraj A 2009 Graphene: the new two-dimensional nanomaterial Angew. Chem. 48 7752–77
    [62]
    Bong S, Kim Y-R, Kim I, Woo S, Uhm S, Lee J and Kim H 2010 Graphene supported electrocatalysts for methanol oxidation Electrochem. Commun. 12 129–31
    [63]
    Lee S H, Kakati N, Jee S H, Maiti J and Yoon Y-S 2011 Hydrothermal synthesis of PtRu nanoparticles supported on graphene sheets for methanol oxidation in direct methanol fuel cell Mater. Lett. 65 3281–4
    [64]
    Navalon S, Dhakshinamoorthy A, Alvaro M and Garcia H 2014 Carbocatalysis by graphene-based materials Chem. Rev. 114 6179–212
    [65]
    Coleman J 2013 Liquid exfoliation of defect-free graphene Acc. Chem. Res. 46 14–22
    [66]
    Deng J, Deng D and Bao X 2017 Robust catalysis on 2D materials encapsulating metals: concept, application, and perspective Adv. Mater. 29 1606967
    [67]
    Deng J, Ren P, Deng D and Bao X 2015 Enhanced electron penetration through an ultrathin graphene layer for highly efficient catalysis of the hydrogen evolution reaction Angew. Chem. 54 2100–4
    [68]
    Tu Y, Deng J, Ma C, Yu L, Bao X and Deng D 2020 Double-layer hybrid chainmail catalyst for highperformance hydrogen evolution Nano Energy 72 104700
    [69]
    Fan X, Zhang G and Zhang F 2015 Multiple roles of graphene in heterogeneous catalysis Chem. Soc. Rev. 44 3023–35
    [70]
    Cheng Q, Hu C, Wang G, Zou Z, Yang H and Dai L 2020 Carbon-defect-driven electroless deposition of Pt atomic clusters for highly efficient hydrogen evolution J. Am. Chem. Soc. 142 5594–601
    [71]
    Peng K, Wang H, Gao H, Wan P, Ma M and Li X 2020 Emerging hierarchical ternary 2D nanocomposites constructed from montmorillonite, graphene and MoS2 for enhanced electrochemical hydrogen evolution Chem. Eng. J. 393 124704
    [72]
    Zhuang W, Li Z, Song M, Zhu W and Tian L 2022 Synergistic improvement in electron transport and active sites exposure over RGO supported NiP/Fe4 P for oxygen evolution reaction Ionics 28 1–8
    [73]
    Li W, Yu B, Hu Y, Wang X, Yang D and Chen Y 2019 Core– shell structure of NiSe2 Nanoparticles@Nitrogen-doped graphene for hydrogen evolution reaction in both acidic and alkaline media ACS Sustain. Chem. Eng. 7 4351–9
    [74]
    Li B, Li Z, Pang Q and Zhang J Z 2020 Core/shell cable-like Ni3S2 nanowires/N-doped graphene-like carbon layers as composite electrocatalyst for overall electrocatalytic water splitting Chem. Eng. J. 401 126045
    [75]
    Wu L, Yu L, McElhenny B, Xing X, Luo D, Zhang F, Bao J, Chen S and Ren Z 2021 Rational design of core-shellstructured CoP@FeOOH for efficient seawater electrolysis Appl. Catal. B 294 120256
    [76]
    Zhang B, Xu W, Liu S, Chen X, Ma T, Wang G, Lu Z and Sun J 2021 Enhanced interface interaction in Cu2S@Ni core-shell nanorod arrays as hydrogen evolution reaction electrode for alkaline seawater electrolysis J. Power Sources 506 230235
    [77]
    Zhang L, Lei Y, Zhou D, Xiong C, Jiang Z, Li X, Shang H, Zhao Y, Chen W and Zhang B 2021 Interfacial engineering of 3D hollow CoSe2@ultrathin MoSe2 core@shell heterostructure for efficient pH-universal hydrogen evolution reaction Nano Res. 15 2895–904
    [78]
    Xu X, Zhang Q, Yu Y, Chen W, Hu H and Li H 2016 Naturally dried graphene aerogels with superelasticity and tunable Poisson’s ratio Adv. Mater. 28 9223–30
    [79]
    Liu H, Chen D, Wang Z, Jing H and Zhang R 2017 Microwave-assisted molten-salt rapid synthesis of isotype triazine-/heptazine based g-C3N4 heterojunctions with highly enhanced photocatalytic hydrogen evolution performance Appl. Catal. B 203 300–13
    [80]
    Yin L, Chen D, Cui X, Ge L, Yang J, Yu L, Zhang B, Zhang R and Shao G 2014 Normal-pressure microwave rapid synthesis of hierarchical SnO2@rGO nanostructures with superhigh surface areas as high-quality gas-sensing and electrochemical active materials Nanoscale 6 13690–700
    [81]
    Hoque M A, Hassan F M, Higgins D, Choi J-Y, Pritzker M, Knights S, Ye S and Chen Z 2015 Multigrain platinum nanowires consisting of oriented nanoparticles anchored on sulfur-doped graphene as a highly active and durable oxygen reduction electrocatalyst Adv. Mater. 27 1229–34
    [82]
    Duan J, Chen S, Chambers B A, Andersson G G and Qiao S Z 2015 3D WS2 Nanolayers@Heteroatom-doped graphene films as hydrogen evolution catalyst electrodes Adv. Mater. 27 4234–41
    [83]
    Li S, Yu Z, Yang Y, Liu Y, Zou H, Yang H, Jin J and Ma J 2017 Nitrogen-doped truncated carbon nanotubes inserted into nitrogen-doped graphene nanosheets with a sandwich structure: a highly efficient metal-free catalyst for the HER J. Mater. Chem. A 5 6405–10
    [84]
    Chen H-A, Hsin C-L, Huang Y-T, Tang M L, Dhuey S, Cabrini S, Wu W-W and Leone S R 2013 Measurement of interlayer screening length of layered graphene by plasmonic nanostructure resonances J. Phys. Chem. C 117 22211–7
    [85]
    Guinea F 2007 Charge distribution and screening in layered graphene systems Phys. Rev. B 75 235433
    [86]
    Li M, Gu Y, Chang Y, Gu X, Tian J, Wu X and Feng L 2021 Iron doped cobalt fluoride derived from CoFe layered double hydroxide for efficient oxygen evolution reaction Chem. Eng. J. 425 130686
    [87]
    Liu H, Liu Z, Wang F and Feng L 2020 Efficient catalysis of N doped NiS/NiS2 heterogeneous structure Chem. Eng. J. 397 125507
    [88]
    Wang Q, He R, Yang F, Tian X, Sui H and Feng L 2023 An overview of heteroatom doped cobalt phosphide for efficient electrochemical water splitting Chem. Eng. J. 456 141056
    [89]
    Zheng Y, Jiao Y, Li L H, Xing T, Chen Y, Jaroniec M and Qiao S Z 2014 Toward design of synergistically active carbon-based catalysts for electrocatalytic hydrogen evolution ACS Nano 8 5290–6
    [90]
    Yang Y, Lin Z, Gao S, Su J, Lun Z, Xia G, Chen J, Zhang R and Chen Q 2016 Tuning electronic structures of nonprecious ternary alloys encapsulated in graphene layers for optimizing overall water splitting activity ACS Catal. 7 469–79
    [91]
    Najafi L, Bellani S, Oropesa-Nu˜nez R, Martín-García B, Prato M and Bonaccorso F 2019 Single-/few-layer graphene as long-lasting electrocatalyst for hydrogen evolution reaction ACS Appl. Energy Mater. 2 5373–9
    [92]
    Yu J, Du Y, Li Q, Zhen L, Dravid V P, Wu J and Xu C-Y 2019 In-situ growth of graphene decorated Ni3S2 pyramids on Ni foam for high-performance overall water splitting Appl. Surf. Sci. 465 772–9
    [93]
    Chen D, Feng H and Li J 2012 Graphene oxide: preparation, functionalization, and electrochemical applications Chem. Rev. 112 6027–53
    [94]
    Gao W (ed) 2015 The chemistry of graphene oxide Graphene Oxide: Reduction Recipes, Spectroscopy, and Applications (springer) pp 61–95
    [95]
    Reina A, Jia X, Ho J, Nezich D, Son H, Bulovic V, Dresselhaus M S and Kong J 2009 Large area, few-layer graphene films on arbitrary substrates by chemical vapor deposition Nano Lett. 9 30–35
    [96]
    Chaitoglou S, Giannakopoulou T, Papanastasiou G, Tsoutsou D, Vavouliotis A, Trapalis C and Dimoulas A 2020 Cu vapor-assisted formation of nanostructured Mo2C electrocatalysts via direct chemical conversion of Mo surface for efficient hydrogen evolution reaction applications Appl. Surf. Sci. 510 145516
    [97]
    Zhao G, Rui K, Dou S X and Sun W 2018 Heterostructures for electrochemical hydrogen evolution reaction: a review Adv. Funct. Mater. 28 1803291
    [98]
    Blackstone C and Ignaszak A 2021 Van der Waals heterostructures-recent progress in electrode materials for clean energy applications Materials 14 3754
    [99]
    Suragtkhuu S, Bat-Erdene M, Bati A S R, Shapter J G, Davaasambuu S and Batmunkh M 2020 Few-layer black phosphorus and boron-doped graphene based heteroelectrocatalyst for enhanced hydrogen evolutionn J. Mater. Chem. A 8 20446–52
    [100]
    Vazquez Sulleiro M et al 2022 Fabrication of devices featuring covalently linked MoS2-graphene heterostructures Nat. Chem. 14 695–700
    [101]
    Zhang J, Yan Y, Wang X, Cui Y, Zhang Z, Wang S, Xie Z, Yan P and Chen W 2023 Bridging multiscale interfaces for developing ionically conductive high-voltage iron sulfate-containing sodium-based battery positive electrodes Nat. Commun. 14 3701
    [102]
    Li W, Guo X, Song K, Chen J, Zhang J, Tang G, Liu C, Chen W and Shen C 2023 Binder-induced ultrathin SEI for defect-passivated hard carbon enables highly reversible sodium-ion storage Adv. Energy Mater. 13 2300648
    [103]
    Su H, Gorlin Y, Man I C, Calle-Vallejo F, Nørskov J K, Jaramillo T F and Rossmeisl J 2012 Identifying active surface phases for metal oxide electrocatalysts: a study of manganese oxide bi-functional catalysts for oxygen reduction and water oxidation catalysis Phys. Chem. Chem. Phys. 14 14010–22
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