Contribution of metal-hydride species on the catalysts to catalytic performances

Shisi Tang; Xiao Cai; Weiping Ding; Yan Zhu

doi:10.20517/cs.2024.162

Chemical Synthesis ›› 2026, Vol. 6 ›› Issue (2) :19 DOI: 10.20517/cs.2024.162

Review

Contribution of metal-hydride species on the catalysts to catalytic performances

Author information +

History +

PDF

Abstract

Metal-hydride (M-H) species typically exhibit high reactivities and distinctive chemical properties, which have prompted extensive investigations within the field of catalysis. Metal hydrides possess abundant M-H species within their structural composition, which can serve as extra hydrogen sources for chemical reactions in many cases. Additionally, they exhibit distinctive hydrogen absorption and desorption properties, making them a promising class of catalysts for hydrogenation and dehydrogenation reactions. In this Review, the mechanism and characterization of M-H species in catalytic reactions for M-H particles, molecular metal hydrides and hydride-doped metal nanoclusters were reviewed and compared. When metal oxides are used as catalysts, H₂ can generally crack at the surface to produce highly M-H species to promote the reaction. Nevertheless, the intricate surface configuration of the catalyst and the transient nature of M-H intermediates have presented significant challenges in terms of detecting and characterizing them. A fundamental understanding of the reaction mechanisms and dynamic changes of M-H species could help design highly efficient catalysts for chemical reactions involving hydrogen.

Keywords

Metal-hydride species / heterogeneous catalysts / homogeneous catalysts / molecular metal hydrides / hydride-doped metal nanoclusters / reaction mechanism

Cite this article

Download citation ▾

Shisi Tang, Xiao Cai, Weiping Ding, Yan Zhu. Contribution of metal-hydride species on the catalysts to catalytic performances. Chemical Synthesis, 2026, 6(2): 19 DOI:10.20517/cs.2024.162

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Norton JR.Introduction: metal hydrides.Chem Rev2016;116:8315-7

[2]	Yu H,Zheng J.Beyond hydrogen storage: metal hydrides for catalysis.ACS Catal2024;14:3139-57

[3]	He T,Chen P.Complex hydrides for energy storage, conversion, and utilization.Adv Mater2019;31:e1902757

[4]	Li Z.Hydride species on oxide catalysts.J Phys Condens Matter2021;33:433001

[5]	Xiong M,Qin Y.Spillover in heterogeneous catalysis: new insights and opportunities.ACS Catal2021;11:3159-72

[6]	Copéret C,Larmier K.Isolated surface hydrides: formation, structure, and reactivity.Chem Rev2016;116:8463-505

[7]	Tokmic K,Zhu L.Well-defined cobalt(I) dihydrogen catalyst: experimental evidence for a Co(I)/Co(III) redox process in olefin hydrogenation.J Am Chem Soc2016;138:11907-13

[8]	Tokmic K.Alkyne semihydrogenation with a well-defined nonclassical Co-H₂ catalyst: a H₂ spin on isomerization and E-selectivity.J Am Chem Soc2016;138:13700-5

[9]	Teschner D,Wootsch A.The roles of subsurface carbon and hydrogen in palladium-catalyzed alkyne hydrogenation.Science2008;320:86-9

[10]	Ziebart C,Anbarasan P.Well-defined iron catalyst for improved hydrogenation of carbon dioxide and bicarbonate.J Am Chem Soc2012;134:20701-4

[11]	Zhang X,Meiwes-Broer KH,Bowen K.CO₂ activation and hydrogenation by PtH_n^- cluster anions.Angew Chem Int Ed Engl2016;55:9644-7

[12]	Chen H,Cheng C.Hydrogen activation on aluminium-doped magnesium hydride surface for methanation of carbon dioxide.Appl Surf Sci2020;515:146038

[13]	Wang P,Gao W.Breaking scaling relations to achieve low-temperature ammonia synthesis through LiH-mediated nitrogen transfer and hydrogenation.Nat Chem2017;9:64-70

[14]	Kobayashi Y,Kageyama T.Titanium-based hydrides as heterogeneous catalysts for ammonia synthesis.J Am Chem Soc2017;139:18240-6

[15]	Wang Q,Guo J.Ternary ruthenium complex hydrides for ammonia synthesis via the associative mechanism.Nat Catal2021;4:959-67

[16]	Spektor K,Filippov S,Häussermann U.Exploring the Mg-Cr-H system at high pressure and temperature via in situ synchrotron diffraction.Inorg Chem2019;58:11043-50

[17]	Soga K,Ikeda S.Hydrogenation of ethylene over lanthanum-nickel (LaNi5) alloy.J Phys Chem1977;81:1762-6

[18]	Soga K.Hydrogenation of ethylene over some intermetallic compounds.J Catal1979;56:119-26

[19]	Barrault J,Percheron-Guegan A,Achard J.Olefin hydrogenation over some LaNi_5-xM_x intermetallic systems.Appl Catal1986;22:263-71

[20]	Johnson J.Behavior of hydrided and dehydrided LaNi₅H_x as an hydrogenation catalyst.J Catal1992;137:102-13

[21]	Yu H,Jiang X.LaNi_5.5 particles for reversible hydrogen storage in N-ethylcarbazole.Nano Energy2021;80:105476

[22]	Zhong D,Liu J,Jia Y.Metallic Ni nanocatalyst in situ formed from LaNi₅H₅ toward efficient CO₂ methanation.Int J Hydrogen Energy2019;44:29068-74

[23]	Yang S,Li Y,Hu L.Effect of substituting B for Ni on electrochemical kinetic properties of AB₅-type hydrogen storage alloys for high-power nickel/metal hydride batteries.Mater Sci Eng B2011;176:231-6

[24]	Choi HS.Theoretical guidelines to designing high performance energy storage device based on hybridization of lithium-ion battery and supercapacitor.J Power Sources2014;259:1-14

[25]	Kato S,Kerger P.The origin of the catalytic activity of a metal hydride in CO₂ reduction.Angew Chem Int Ed Engl2016;55:6028-32

[26]	Kato S,Ferri D.CO₂ hydrogenation on a metal hydride surface.Phys Chem Chem Phys2012;14:5518-26

[27]	Hou Z,Zhang X.Hydrogen storage and stability of rare earth-doped TiFe alloys under extensive cycling.Int J Hydrogen Energy2025;136:469-76

[28]	Iribarren I,Elguero J,Trujillo C.Reactivity of coinage metal hydrides for the production of H₂ molecules.ChemistryOpen2021;10:724-30

[29]	Gao W,Wang P.Production of ammonia via a chemical looping process based on metal imides as nitrogen carriers.Nat Energy2018;3:1067-75

[30]	Gao W,Guo J.Barium hydride-mediated nitrogen transfer and hydrogenation for ammonia synthesis: a case study of cobalt.ACS Catal2017;7:3654-61

[31]	Chang F,Chang X.Alkali and alkaline earth hydrides-driven N₂ activation and transformation over Mn nitride catalyst.J Am Chem Soc2018;140:14799-806

[32]	Hattori M,Arai T.Enhanced catalytic ammonia synthesis with transformed BaO.ACS Catal2018;8:10977-84

[33]	Chen H,Li J.MgH₂/Cu_xO hydrogen storage composite with defect-rich surfaces for carbon dioxide hydrogenation.ACS Appl Mater Interfaces2019;11:31009-17

[34]	Chen H,Liu J,Zhou S.Mechanochemical in-situ incorporation of Ni on MgO/MgH₂ surface for the selective O-/C-terminal catalytic hydrogenation of CO₂ to CH₄.J Catal2021;394:397-405

[35]	Heiber W.Äthylendiamin-substituierte Eisencarboyle und eine neue Bildungsweise von Eisencarbonylwasserstoff (XI. Mitteil. über Metallcarbonyle).Ber dtsch Chem Ges A/B1931;64:2832-9

[36]	Babón JC,López AM.Homogeneous catalysis with polyhydride complexes.Chem Soc Rev2022;51:9717-58

[37]	Ortuño MA,Conejero S.Orbital-like motion of hydride ligands around low-coordinate metal centers.Angew Chem Int Ed Engl2014;53:14158-61

[38]	Morris RH.Estimating the acidity of transition metal hydride and dihydrogen complexes by adding ligand acidity constants.J Am Chem Soc2014;136:1948-59

[39]	Morris RH.Brønsted-Lowry acid strength of metal hydride and dihydrogen complexes.Chem Rev2016;116:8588-654

[40]	Zhu Y,Burgess K.Carbene-metal hydrides can be much less acidic than phosphine-metal hydrides: significance in hydrogenations.J Am Chem Soc2010;132:6249-53

[41]	Wiedner ES,Pitman CL,Miller AJ.Thermodynamic hydricity of transition metal hydrides.Chem Rev2016;116:8655-92

[42]	Sasson Y.Homogeneous rearrangement of unsaturated carbinols to saturated ketones catalyzed by ruthenium complexes.Tetrahedron Lett1974;15:4133-6

[43]	Yadav S.Base-free transfer hydrogenation catalyzed by ruthenium hydride complexes of coumarin-amide ligands.ACS Sustain Chem Eng2023;11:8533-43

[44]	Pandey B,Guan H.Cobalt-catalyzed additive-free dehydrogenation of neat formic acid.ACS Catal2024;14:13781-91

[45]	Liu T,Orthaber A.Accelerating proton-coupled electron transfer of metal hydrides in catalyst model reactions.Nat Chem2018;10:881-7

[46]	Roberts JA,DuBois DL.Comprehensive thermochemistry of W-H bonding in the metal hydrides CpW(CO)₂(IMes)H, [CpW(CO)₂(IMes)H]^•+, and [CpW(CO)₂(IMes)(H)₂]⁺. Influence of an N-heterocyclic carbene ligand on metal hydride bond energies.J Am Chem Soc2011;133:14604-13

[47]	Esteruelas MA,Martínez A,Oñate E.Osmium hydride acetylacetonate complexes and their application in acceptorless dehydrogenative coupling of alcohols and amines and for the dehydrogenation of cyclic amines.Organometallics2017;36:2996-3004

[48]	Buil ML,Gay MP.Osmium catalysts for acceptorless and base-free dehydrogenation of alcohols and amines: unusual coordination modes of a BPI anion.Organometallics2018;37:603-17

[49]	Zeiher EHK,Caulton KG.Mechanistic features of carbon-hydrogen bond activation by the rhenium complex ReH7[P(C6H11)3]2.J Am Chem Soc1984;106:7006-11

[50]	Lapointe S,Gallagher JM.Cobalt complexes of bulky PNP ligand: H₂ activation and catalytic two-electron reactivity in hydrogenation of alkenes and alkynes.Organometallics2021;40:3617-26

[51]	Borowski AF,Christ ML,Chaudret B.Versatile reactivity of the bis(dihydrogen) complex RuH₂(H₂)₂(PCy₃)₂ toward functionalized olefins: olefin coordination versus hydrogen transfer via the stepwise dehydrogenation of the phosphine ligand.Organometallics1996;15:1427-34

[52]	Borowski AF,Chaudret B.Homogeneous hydrogenation of arenes catalyzed by the bis(dihydrogen) complex [RuH₂(H₂)₂(PCy₃)₂].J Mol Catal A Chem2001;174:69-79

[53]	Borowski AF,Sabo-Etienne S,Gaudyn AV.Catalyzed hydrogenation of condensed three-ring arenes and their N-heteroaromatic analogues by a bis(dihydrogen) ruthenium complex.Dalton Trans2012;41:14117-25

[54]	Dobereiner GE,Schley ND.Iridium-catalyzed hydrogenation of N-heterocyclic compounds under mild conditions by an outer-sphere pathway.J Am Chem Soc2011;133:7547-62

[55]	Anker MD,Lowe JP.Alkaline-earth-promoted CO homologation and reductive catalysis.Angew Chem Int Ed Engl2015;54:10009-11 PMCID:PMC4678424

[56]	Shi X,Wang Y,Liu Z.Super-bulky penta-arylcyclopentadienyl ligands: isolation of the full range of half-sandwich heavy alkaline-earth metal hydrides.Angew Chem Int Ed Engl2019;58:4356-60

[57]	Jin R,Sharma S,Du X.Toward active-site tailoring in heterogeneous catalysis by atomically precise metal nanoclusters with crystallographic structures.Chem Rev2021;121:567-648

[58]	Zhao S,Jin R.Opportunities and challenges in CO₂ reduction by gold- and silver-based electrocatalysts: from bulk metals to nanoparticles and atomically precise nanoclusters.ACS Energy Lett2018;3:452-62

[59]	Gross E.Mesoscale nanostructures as a bridge between homogeneous and heterogeneous catalysis.Top Catal2014;57:812-21

[60]	Sun C,Deng C.Hydrido-coinage-metal clusters: rational design, synthetic protocols and structural characteristics.Coord Chem Rev2021;427:213576

[61]	Chiu TH,Silalahi RPB,Liu CW.Hydride-doped coinage metal superatoms and their catalytic applications.Nanoscale Horiz2024;9:675-92

[62]	Sun C,Kaappa S.Atomically precise, thiolated copper-hydride nanoclusters as single-site hydrogenation catalysts for ketones in mild conditions.ACS Nano2019;13:5975-86 PMCID:PMC6750866

[63]	Liu CY,Guan ZJ.Dramatic difference between Cu₂₀H₈ and Cu₂₀H₉ clusters in catalysis.CCS Chem2024;6:1581-90

[64]	Ni YR,Chiu TH.Controlled shell and kernel modifications of atomically precise Pd/Ag superatomic nanoclusters.Chemistry2023;29:e202300730

[65]	Yuan SF,Wang QM.Identification of the active species in bimetallic cluster catalyzed hydrogenation.J Am Chem Soc2022;144:11405-12

[66]	Liu CY,Wang S,Jiang DE.Structural transformation and catalytic hydrogenation activity of amidinate-protected copper hydride clusters.Nat Commun2022;13:2082 PMCID:PMC9018778

[67]	Kulkarni VK,Takano S.N-heterocyclic carbene-stabilized hydrido Au₂₄ nanoclusters: synthesis, structure, and electrocatalytic reduction of CO₂.J Am Chem Soc2022;144:9000-6

[68]	Gao ZH,Wu T.A heteroleptic gold hydride nanocluster for efficient and selective electrocatalytic reduction of CO₂ to CO.J Am Chem Soc2022;144:5258-62

[69]	Tang L,Ma X.Poly-hydride [Au^I₇(PPh₃)₇H₅](SbF₆)₂ cluster complex: structure, transformation, and electrocatalytic CO₂ reduction properties.Angew Chem Int Ed Engl2023;62:e202300553

[70]	Brocha Silalahi RP,Liao JH.Hydride-containing 2-electron Pd/Cu superatoms as catalysts for efficient electrochemical hydrogen evolution.Angew Chem Int Ed Engl2023;62:e202301272

[71]	Chen H,Liu Z.Direct detection of reactive gallium-hydride species on the Ga₂O₃ surface via solid-state NMR spectroscopy.J Am Chem Soc2022;144:17365-75

[72]	Wang M,Wang G.Spinel nanostructures for the hydrogenation of CO₂ to methanol and hydrocarbon chemicals.J Am Chem Soc2024;146:14528-38

[73]	Chen L,Pez GP.On the mechanisms of hydrogen spillover in MoO₃.J Phys Chem C2008;112:1755-8

[74]	Xi Y,Cheng H.Mechanism of hydrogen spillover on WO₃(001) and Formation of H_xWO₃ (x = 0.125, 0.25, 0.375, and 0.5).J Phys Chem C2014;118:494-501

[75]	Khoobiar S.Particle to particle migration of hydrogen atoms on platinum - alumina catalysts from particle to neighboring particles.J Phys Chem1964;68:411-2

[76]	Benseradj F,Chater M.Hydrogen spillover studies on diluted Rh/Al₂O₃ catalyst.Appl Catal A Gen2002;228:135-44

[77]	Antonucci P.Hydrogen spillover effects in the hydrogenation of benzene over Ptγ-Al₂O₃ catalysts.J Catal1982;75:140-50

[78]	Kang H,Li S.Generation of oxide surface patches promoting H-spillover in Ru/(TiO_x)MnO catalysts enables CO₂ reduction to CO.Nat Catal2023;6:1062-72