The emerging Sr2FeMoO6-based electrocatalysts for solid oxide electrochemical cell: synthesis, modulation and applications

Yuanfeng Liao; Xiuan Xi; Hao Chen; Jianwen Liu; Xian-Zhu Fu; Jing-Li Luo

doi:10.20517/cs.2023.47

Chemical Synthesis ›› 2024, Vol. 4 ›› Issue (2) :18 DOI: 10.20517/cs.2023.47

review-article

The emerging Sr₂FeMoO₆-based electrocatalysts for solid oxide electrochemical cell: synthesis, modulation and applications

Author information +

History +

PDF

Abstract

Solid oxide cells (SOCs) are regarded as a promising energy technology due to their large current density, diverse range of fuels, and high energy conversion efficiency. The double perovskite Sr₂FeMoO₆ (SFM) has attracted considerable attention for SOCs due to its tunable structure with superior performance of high conductivity, excellent thermal stability, and remarkable carbon deposition resistance in a reducing atmosphere. However, the electrocatalytic activity of SFM is considerably lower than that of commercial Ni-based SOC electrodes. A timely summary of the synthesis, modulation, and application of SFM perovskites is of great significance for its further development for SOCs. In this review, the methods employed in the preparation of SFM electrocatalysts are introduced first. Then, the advancements in the application of different SFM-based electrocatalysts in the field of SOCs are reviewed, and the research progress in the in-situ exsolution of SFM-based electrocatalysts through ion regulation is assessed. Finally, the future issues associated with SFM-based electrocatalysts are addressed in the realm of electrocatalysis, to advance their application.

Keywords

Solid oxide cells / perovskite oxides / Sr₂FeMoO₆ / electrocatalysts / element doping / in-situ exsolution

Cite this article

Download citation ▾

Yuanfeng Liao, Xiuan Xi, Hao Chen, Jianwen Liu, Xian-Zhu Fu, Jing-Li Luo. The emerging Sr₂FeMoO₆-based electrocatalysts for solid oxide electrochemical cell: synthesis, modulation and applications. Chemical Synthesis, 2024, 4(2): 18 DOI:10.20517/cs.2023.47

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]	Gür TM.Carbon dioxide emissions, capture, storage and utilization: review of materials, processes and technologies.Prog Energy Combust Sci2022;89:100965

[2]	Pan X,Zheng X,Ma X.Energy and sustainable development nexus: a review.Energy Strategy Rev2023;47:101078

[3]	Li W.High-temperature electrochemical devices based on dense ceramic membranes for CO₂ conversion and utilization.Electrochem Energ Rev2021;4:518-44

[4]	Li Y,Zheng Y.Controlling cation segregation in perovskite-based electrodes for high electro-catalytic activity and durability.Chem Soc Rev2017;46:6345-78

[5]	Cao J,Shao Z.Nanotechnologies in ceramic electrochemical cells.Chem Soc Rev2024;53:450-501

[6]	Wang W,Wu Y,Shao Z.Progress in solid oxide fuel cells with nickel-based anodes operating on methane and related fuels.Chem Rev2013;113:8104-51

[7]	Si F,Liang Y,Zhang J.Fuel cell reactors for the clean cogeneration of electrical energy and value-added chemicals.Electrochem Energy Rev2022;5:25

[8]	Zhang W,Zhou Y.A solid oxide fuel cell runs on hydrocarbon fuels with exceptional durability and power output.Adv Energy Mater2022;12:2202928

[9]	Song Y,Xie K,Bao X.High-temperature CO₂ electrolysis in solid oxide electrolysis cells: developments, challenges, and prospects.Adv Mater2019;31:1902033

[10]	Boldrin P.Progress and outlook for solid oxide fuel cells for transportation applications.Nat Catal2019;2:571-7

[11]	Cao J,Shao Z.Perovskites for protonic ceramic fuel cells: a review.Energy Environ Sci2022;15:2200-32

[12]	Cheng Z,Choi Y,Lin MC.From Ni-YSZ to sulfur-tolerant anode materials for SOFCs: electrochemical behavior, in situ characterization, modeling, and future perspectives.Energy Environ Sci2011;4:4380

[13]	Connor PA,Savaniu CD.Tailoring SOFC electrode microstructures for improved performance.Adv Energy Mater2018;8:1800120

[14]	Wang JH,Brédas JL.Electronic and vibrational properties of nickel sulfides from first principles.J Chem Phys2007;127:214705

[15]	Gong M,Trembly J.Sulfur-tolerant anode materials for solid oxide fuel cell application.J Power Sources2007;168:289-98

[16]	Yang L,Liu M.New insights into sulfur poisoning behavior of Ni-YSZ anode from long-term operation of anode-supported SOFCs.Energy Environ Sci2010;3:1804-9

[17]	Boldrin P,Mermelstein J,Ramı Rez Reina T.Strategies for carbon and sulfur tolerant solid oxide fuel cell materials, incorporating lessons from heterogeneous catalysis.Chem Rev2016;116:13633-84

[18]	Li Y,Xia C.Highly efficient electrolysis of pure CO₂ with symmetrical nanostructured perovskite electrodes.Catal Sci Technol2018;8:980-4

[19]	Wang Z,Li Y.Direct CH4 fuel cell using Sr₂FeMoO₆ as an anode material.J Power Sources2011;196:6104-9

[20]	Cernea M,Bartha C,Mercioniu I.Characterization of ferromagnetic double perovskite Sr₂FeMoO₆ prepared by various methods.Ceram Int2014;40:11601-9

[21]	Cernea M,Plapcianu C.Preparation by sol-gel and solid state reaction methods and properties investigation of double perovskite Sr₂FeMoO₆.J Eur Ceram Soc2013;33:2483-90

[22]	Rager J,Sharma A.Oxygen stoichiometry in Sr₂FeMoO₆, the determination of Fe and Mo valence states, and the chemical phase diagram of SrO-Fe₃O₄-MoO₃.J Am Ceram Soc2004;87:1330-5

[23]	Farzin YA,Ataie A.Low-temperature synthesis of Sr₂FeMoO₆ double perovskite; structure, morphology, and magnetic properties.Ceram Int2020;46:16867-78

[24]	Das R,Mahendiran R.Microwave magnetoresistance and microwave absorption in Sr₂FeMoO₆.ACS Appl Electron Mater2021;3:3072-8

[25]	Zhai Y,Huo G.Synthesis, magnetic and electrical transport properties of magnetoresistance material Sr₂FeMoO₆ by microwave sintering.J Magn Magn Mater2012;324:2006-10

[26]	Li XY,Zhang LY,Dai ZX.Generation of oxygen vacancies on Sr₂FeMoO₆ to improve its photocatalytic performance through a novel preparation method involving pH adjustment and use of surfactant.Appl Surf Sci2019;480:262-75

[27]	Mami A,Mellouki I.Synthesis and physical characterization of Sr₂FeMoO₆ and Sr₃FeMoO₇ thin films.Mater Lett2019;243:77-80

[28]	Valdés J,Cuán Á.Sol-gel synthesis of the double perovskite Sr₂FeMoO₆ by microwave technique.Material2021;14:3876 PMCID:PMC8305548

[29]	Kumar A,Kim S.Solid-state reaction synthesis of nanoscale materials: strategies and applications.Chem Rev2022;122:12748-863

[30]	Raittila J,Suominen T,Paturi P.Nanocrystalline Sr₂FeMoO₆ prepared by citrate-gel method.J Phys Chem Solids2006;67:1712-8

[31]	Xi X,Fan Y.Reducing d-p band coupling to enhance CO₂ electrocatalytic activity by Mg-doping in Sr₂FeMoO_6-δ double perovskite for high performance solid oxide electrolysis cells.Nano Energy2021;82:105707

[32]	Du Z,Li S.Exceptionally high performance anode material based on lattice structure decorated double perovskite Sr₂FeMo_2/3Mg_1/3O_6-_δ for solid oxide fuel cells.Adv Energy Mater2018;8:1800062

[33]	Das R,Pradhan D.Structural and electrical characteristics of double perovskite: Sr₂FeMoO₆.Mater Sci Eng B2022;281:115715

[34]	Wang J,Wardini JL.Exsolution-driven surface transformation in the host oxide.Nano Lett2022;22:5401-8

[35]	Kousi K,Metcalfe IS.Emergence and future of exsolved materials.Small2021;17:e2006479

[36]	Ding D,Lai SY,Liu M.Enhancing SOFC cathode performance by surface modification through infiltration.Energy Environ Sci2014;7:552-75

[37]	Du Z,Yi S.High-performance anode material Sr₂FeMo_0.65Ni_0.35O_6-δ with in situ exsolved nanoparticle catalyst.ACS Nano2016;10:8660-9

[38]	Xi X,Zhang J,Fu X.In situ construction of hetero-structured perovskite composites with exsolved Fe and Cu metallic nanoparticles as efficient CO₂ reduction electrocatalysts for high performance solid oxide electrolysis cells.J Mater Chem A2022;10:2509-18

[39]	Yang M,Liu S.Bismuth doped Sr₂Fe_1.5Mo_0.5O_6-_δ double perovskite as a robust fuel electrode in ceramic oxide cells for direct CO₂ electrolysis.J Mater Sci Technol2023;164:160-7

[40]	Muñoz-García AB.K-doped Sr₂Fe_1.5Mo_0.5O_6-_δ predicted as a bifunctional catalyst for air electrodes in proton-conducting solid oxide electrochemical cells.J Mater Chem A2017;5:12735-9

[41]	Muñoz-García AB,Carter EA.Effect of antisite defects on the formation of oxygen vacancies in Sr₂FeMoO₆: implications for ion and electron transport.Chem Mater2011;23:4525-36

[42]	Reyes AM,Navarro O.Effect of cationic disorder on the magnetic moment of Sr₂FeMoO₆: ab initio calculations.J Phys Chem C2016;120:4048-52

[43]	Mishra R,Woodward PM.First-principles study of defective and nonstoichiometric Sr₂FeMoO₆.Chem Mater2010;22:6092-102

[44]	Sunarso J,Zhu N.Perovskite oxides applications in high temperature oxygen separation, solid oxide fuel cell and membrane reactor: a review.Prog Energy Combust Sci2017;61:57-77

[45]	Yin W,Ge J,Li Z.Oxide perovskites, double perovskites and derivatives for electrocatalysis, photocatalysis, and photovoltaics.Energy Environ Sci2019;12:442-62

[46]	Kozuka H,Koumoto K.Electronic conduction in La-based perovskite-type oxides.Sci Technol Adv Mater2015;16:026001 PMCID:PMC5036473

[47]	Bartha C,Crisan A,Leca A. Structural and magnetic properties of Sr₂FeMoO₆ obtained at low temperatures. Available from: https://www.chalcogen.ro/773_BarthaC.pdf. [Last accessed on 21 Feb 2024]

[48]	Saloaro M,Adeagbo WA.Toward versatile Sr₂FeMoO₆-based spintronics by exploiting nanoscale defects.ACS Appl Mater Interfaces2016;8:20440-7

[49]	Xi X,Luo W.Unraveling the enhanced kinetics of Sr₂Fe₁₊_xMo_1-_xO_6-δ electrocatalysts for high-performance solid oxide cells.Adv Energy Mater2021;11:2102845

[50]	Kobayashi KI,Sawada H,Tokura Y.Room-temperature magnetoresistance in an oxide material with an ordered double-perovskite structure.Nature1998;395:677-680.

[51]	Phuyal D,Panda SK.Nonlocal interactions in the double perovskite Sr₂FeMoO₆ from core-level X-ray spectroscopy.J Phys Chem C2021;125:11249-56

[52]	Varma A,Rogachev AS.Solution combustion synthesis of nanoscale materials.Chem Rev2016;116:14493-586

[53]	Feinle A,Hüsing N.Sol-gel synthesis of monolithic materials with hierarchical porosity.Chem Soc Rev2016;45:3377-99

[54]	Li C,Junmin X.Mechanically activated synthesis and magnetoresistance of nanocrystalline double perovskite Sr₂FeMoO₆.J Am Ceram Soc2005;88:2635-8

[55]	Martynczuk J,Wang H,Feldhoff A.How (Ba_0.5Sr_0.5)(Fe_0.8Zn_0.2)O_3-δ and (Ba_0.5Sr_0.5)(Co_0.8Fe_0.2)O_3-δ perovskites form via an EDTA/citric acid complexing method.Adv Mater2007;19:2134-40

[56]	Hu Y,Wang X.Effect of gas flow rate on transport properties of Sr₂FeMoO₆.J Magn Magn Mater2022;553:169234

[57]	Angervo I,Tikkanen J,Paturi P.Improving the surface structure of high quality Sr₂FeMoO₆ thin films for multilayer structures.Appl Surf Sci2017;396:754-9

[58]	Jacobo SE.Novel method of synthesis for double-perovskite Sr₂FeMoO₆.J Mater Sci2005;40:417-21

[59]	Takeda T,Kikkawa S.Preparation of magneto-resistive Sr₂FeMoO₆ through molybdic acid gelation.J Alloys Compd2008;449:93-5

[60]	E P,Yao LD.The structural and electrical properties of nano-scale Sr₂FeMoO₆ under high pressures.J Mater Sci2006;41:7374-9

[61]	Yang D,Sun Q,Lampronti GI.The annealing effects on the crystal structure, magnetism and microstructure of the ferromagnetic double perovskite Sr₂FeMoO₆ synthesized via spark plasma sintering.J Alloys Compd2017;728:337-42

[62]	Yang CW.Structures and development mechanism of the anti-phase boundaries in Sr₂FeMoO₆.J Electrochem Soc2012;159:P35

[63]	Taylor DD,Brown CM,Rodriguez EE.Stabilization of cubic Sr₂FeMoO₆ through topochemical reduction.Chem Commun2015;51:12201-4

[64]	Wang K.Influence of the modulating interfacial state on Sr₂FeMoO₆ powder magnetoresistance properties.Solid State Commun2004;129:135-8

[65]	Zhang L,He Q.Double-perovskites A₂FeMoO_6-_δ (A = Ca, Sr, Ba) as anodes for solid oxide fuel cells.J Power Sources2010;195:6356-66

[66]	Huan Y,Yin B,Wei T.High conductive and long-term phase stable anode materials for SOFCs: A₂FeMoO₆ (A = Ca, Sr, Ba).J Power Sources2017;359:384-90

[67]	Xi X,Shen X.In situ embedding of CoFe nanocatalysts into Sr₃FeMoO₇ matrix as high-performance anode materials for solid oxide fuel cells.J Power Sources2020;459:228071

[68]	Liu Q,Xiao G,Chen F.A novel electrode material for symmetrical SOFCs.Adv Mater2010;22:5478-82

[69]	Liu Q,Dong X.Perovskite Sr₂Fe_1.5Mo_0.5O_6-_δ as electrode materials for symmetrical solid oxide electrolysis cells.Int J Hydrogen Energy2010;35:10039-44

[70]	Liu Q,Xiao G.Sr₂Fe_1.5Mo_0.5O_6-_δ as a regenerative anode for solid oxide fuel cells.J Power Sources2011;196:9148-53

[71]	Zheng Y,Zhang J.Solid oxide electrolysis of H₂O and CO₂ to produce hydrogen and low-carbon fuels.Electrochem Energ Rev2021;4:508-17

[72]	Fabbri E,Binninger T.Dynamic surface self-reconstruction is the key of highly active perovskite nano-electrocatalysts for water splitting.Nat Mater2017;16:925-31

[73]	Long X,Zhao Q.Ru-RuO₂ nano-heterostructures stabilized by the sacrificing oxidation strategy of Mn₃O₄ substrate for boosting acidic oxygen evolution reaction.Appl Catal B Environ2024;343:123559

[74]	Chen H,Wu X.Pt-Co electrocatalysts: syntheses, morphologies, and applications.Small2022;18:e2204100

[75]	Chen H,Liu D.Highly efficient C@Ni-Pd bifunctional electrocatalyst for energy-saving hydrogen evolution and value-added chemicals co-production from ethanol aqueous solution.Chem Eng J2023;474:145639

[76]	Tomar AK,Kim NH.Enabling lattice oxygen participation in a triple perovskite oxide electrocatalyst for the oxygen evolution reaction.ACS Energy Lett2023;8:565-73

[77]	Zhu K,Li M,Zhu X.Perovskites decorated with oxygen vacancies and Fe-Ni alloy nanoparticles as high-efficiency electrocatalysts for the oxygen evolution reaction.J Mater Chem A2017;5:19836-45

[78]	Tan L,Gao Y.Synergistic interaction between in situ exsolved and phosphorized nanoparticles and perovskite oxides for enhanced electrochemical water splitting.Int J Hydrogen Energy2022;47:20016-26

[79]	Shang C,Xu Q.Coordination chemistry in modulating electronic structures of perovskite-type oxide nanocrystals for oxygen evolution catalysis.Coord Chem Rev2023;485:215109

[80]	Kim BJ,Abbott DF.Functional role of Fe-doping in Co-based perovskite oxide catalysts for oxygen evolution reaction.J Am Chem Soc2019;141:5231-40

[81]	Deng H,Zhang W.The electrolyte-layer free fuel cell using a semiconductor-ionic Sr₂Fe_1.5Mo_0.5O_6-δ - Ce_0.8Sm_0.2O_2-δ composite functional membrane.Int J Hydrogen Energy2017;42:25001-7

[82]	Rath MK.Superior electrochemical performance of non-precious Co-Ni-Mo alloy catalyst-impregnated Sr₂FeMoO_6-_δ as an electrode material for symmetric solid oxide fuel cells.Electrochim Acta2016;212:678-85

[83]	Wang W,Regalado Vera CY.Improving the performance for direct electrolysis of CO₂ in solid oxide electrolysis cells with a Sr_1.9Fe_1.5Mo_0.5O_6-_δ electrode via infiltration of Pr₆O₁₁ nanoparticles.J Mater Chem A2023;11:9039-48

[84]	Zhang L,Sun W.Constructing perovskite/alkaline-earth metal composite heterostructure by infiltration to revitalize CO₂ electrolysis.Sep Purif Technol2022;298:121475

[85]	Yu W,Zhang X,Wang Y.Advanced Ru-infiltrated perovskite oxide electrodes for boosting the performance of syngas fueled solid oxide fuel cell.ChemElectroChem2022;9:e202200024

[86]	Osinkin D,Bogdanovich N.Influence of Pr₆O₁₁ on oxygen electroreduction kinetics and electrochemical performance of Sr₂Fe_1.5Mo_0.5O_6-_δ based cathode.J Power Sources2018;392:41-7

[87]	Li M,Fan Y,Fu X.Interface modification of Ru-CeO₂ co-infiltrated SFM electrode and construction of SDC/YSZ bilayer electrolyte for direct CO₂ electrolysis.Electrochim Acta2022;426:140771

[88]	Ji Q,Zhang J,Zhao XS.The role of oxygen vacancies of ABO₃ perovskite oxides in the oxygen reduction reaction.Energy Environ Sci2020;13:1408-28

[89]	Hwang J,Giordano L,Yu Y.Perovskites in catalysis and electrocatalysis.Science2017;358:751-6

[90]	Mahato N,Gupta A,Balani K.Progress in material selection for solid oxide fuel cell technology: a review.Prog Mater Sci2015;72:141-337

[91]	Gao Z,Miller EC,Barnett SA.A perspective on low-temperature solid oxide fuel cells.Energy Environ Sci2016;9:1602-44

[92]	Myung JH,Miller DN.Switching on electrocatalytic activity in solid oxide cells.Nature2016;537:528-31

[93]	Liu S,Fu X.Cogeneration of ethylene and energy in protonic fuel cell with an efficient and stable anode anchored with in-situ exsolved functional metal nanoparticles.Appl Catal B Environ2018;220:283-9

[94]	Neagu D,Miller DN.Nano-socketed nickel particles with enhanced coking resistance grown in situ by redox exsolution.Nat Commun2015;6:8120 PMCID:PMC4579408

[95]	Calì E,Vasudevan R.Real-time insight into the multistage mechanism of nanoparticle exsolution from a perovskite host surface.Nat Commun2023;14:1754 PMCID:PMC10060596

[96]	Zhang S,Han H,Xia C.Perovskite oxyfluoride ceramic with in situ exsolved Ni-Fe nanoparticles for direct CO₂ electrolysis in solid oxide electrolysis cells.ACS Appl Mater Interfaces2022;14:28854-64

[97]	Hu Y,Hu H.Potassium doping effects on the structure and magnetic properties of Sr₂FeMoO₆.J Alloys Compd2012;526:1-5

[98]	Yang X,Panthi D.Electron doping of Sr₂FeMoO_6-_δ as high performance anode materials for solid oxide fuel cells.J Mater Chem A2019;7:733-43

[99]	Azizi F,Azizi A.Effect of La doping on the electrochemical activity of double perovskite oxide Sr₂FeMoO₆ in alkaline medium.J Alloys Compd2009;484:555-60

[100]

Neagu D,Miller DN,Irvine JT.In situ growth of nanoparticles through control of non-stoichiometry.Nat Chem2013;5:916-23

[101]

Mccolm TD.B site doped strontium titanate as a potential SOFC substrate.Ionics2001;7:116-21

[102]

Sun Y,Zeng Y.A-site deficient perovskite: the parent for in situ exsolution of highly active, regenerable nano-particles as SOFC anodes.J Mater Chem A2015;3:11048-56

[103]

Yang G,Sun W.The characteristic of strontium-site deficient perovskites Sr_xFe_1.5Mo_0.5O_6-_δ (x = 1.9-2.0) as intermediate-temperature solid oxide fuel cell cathodes.J Power Sources2014;268:771-7

[104]

Feng J,Wang W,Sun W.Development and performance of anode material based on A-site deficient Sr_2-xFe_1.4Ni_0.1Mo_0.5O_6-δ perovskites for solid oxide fuel cells.Electrochim Acta2016;215:592-9

[105]

Tan T,Huang K.High-performance co-production of electricity and light olefins enabled by exsolved NiFe alloy nanoparticles from a double-perovskite oxide anode in solid oxide-ion-conducting fuel cells.ACS Nano2023;17:13985-96

[106]

Wang Z,Du K,Liu M.A high-entropy layered perovskite coated with in situ exsolved core-shell CuFe@FeO_x nanoparticles for efficient CO₂ electrolysis.Adv Mater2023;36:2312119

[107]

Xiao G,Dong X,Chen F.Sr₂Fe_4/3Mo_2/3O₆ as anodes for solid oxide fuel cells.J Power Sources2010;195:8071-4

[108]

Lv H,Zhang X.In situ exsolved FeNi₃ nanoparticles on nickel doped Sr₂Fe_1.5Mo_0.5O_6-_δ perovskite for efficient electrochemical CO₂ reduction reaction.J Mater Chem A2019;7:11967-75

[109]

Qiu P,Wang W.Redox-reversible electrode material for direct hydrocarbon solid oxide fuel cells.ACS Appl Mater Interfaces2020;12:13988-95

[110]

He F,Zhu F.Building efficient and durable hetero-interfaces on a perovskite-based electrode for electrochemical CO₂ reduction.Adv Energy Mater2022;12:2202175

[111]

Muñoz-García AB,Pavone M.Unveiling structure-property relationships in Sr₂Fe_1.5Mo_0.5O_6-δ, an electrode material for symmetric solid oxide fuel cells.J Am Chem Soc2012;134:6826-33

[112]

Ye L,Huang P.Enhancing CO₂ electrolysis through synergistic control of non-stoichiometry and doping to tune cathode surface structures.Nat Commun2017;8:14785 PMCID:PMC5357311

[113]

Sun YF,Chen J.New opportunity for in situ exsolution of metallic nanoparticles on perovskite parent.Nano Lett2016;16:5303-9

[114]

Yang Y,Sun Y.The metal/oxide heterointerface delivered by solid-based exsolution strategy: a review.Chem Eng J2022;440:135868

[115]

Liu S,Luo JL.Highly stable and efficient catalyst with in situ exsolved Fe-Ni alloy nanospheres socketed on an oxygen deficient perovskite for direct CO₂ electrolysis.ACS Catal2016;6:6219-28

[116]

Tsvetkov N,Sun L,Yildiz B.Improved chemical and electrochemical stability of perovskite oxides with less reducible cations at the surface.Nat Mater2016;15:1010-6

[117]

Song Y, Min J, Guo Y, et al. Surface activation by single Ru atoms for enhanced high-temperature CO₂ electrolysis.Angew Chem Int Ed Engl2024;63:e202313361

[118]

Kim YH,Won BR.Exsolution modeling and control to improve the catalytic activity of nanostructured electrodes.Adv Mater2023;35:e2208984

[119]

Gu J,Bai L,Hu X.Atomically dispersed Fe³⁺ sites catalyze efficient CO₂ electroreduction to CO.Science2019;364:1091-4

[120]

Lv H,Zhang X.In situ investigation of reversible exsolution/dissolution of CoFe alloy nanoparticles in a Co-doped Sr₂Fe_1.5Mo_0.5O_6-_δ cathode for CO₂ electrolysis.Adv Mater2020;32:e1906193

[121]

Lv H,Zhang X.Promoting exsolution of RuFe alloy nanoparticles on Sr₂Fe_1.4Ru_0.1Mo_0.5O_6-_δ via repeated redox manipulations for CO₂ electrolysis.Nat Commun2021;12:5665 PMCID:PMC8476569

[122]

Weber ML,Jin L.Exsolution of embedded nanoparticles in defect engineered perovskite layers.ACS Nano2021;15:4546-60

[123]

Opitz AK,Vonk V.Understanding electrochemical switchability of perovskite-type exsolution catalysts.Nat Commun2020;11:4801 PMCID:PMC7511332

[124]

Zhang BW,Gao MR.Boosting the stability of perovskites with exsolved nanoparticles by B-site supplement mechanism.Nat Commun2022;13:4618 PMCID:PMC9359987

[125]

Zhang BW,Gao MR.Phase transition engineering of host perovskite toward optimal exsolution-facilitated catalysts for carbon dioxide electrolysis.Angew Chem Int Ed Engl2023;62:e202305552

[126]

Hong J,Singh P.Water mediated growth of oriented single crystalline SrCO₃ nanorod arrays on strontium compounds.Sci Rep2021;11:3368 PMCID:PMC7873059

[127]

Fu G,Zhang Y.Capturing critical gem-diol intermediates and hydride transfer for anodic hydrogen production from 5-hydroxymethylfurfural.Nat Commun2023;14:8395 PMCID:PMC10728175

[128]

Sun Z,He J.Regulating the spin state of Fe^III enhances the magnetic effect of the molecular catalysis mechanism.J Am Chem Soc2022;144:8204-13

[129]

Liu J,Wang L,Fu X.Toward excellence of electrocatalyst design by emerging descriptor-oriented machine learning.Adv Funct Mater2022;32:2110748

[130]

Li J,Xu S,Mu S. Function of electron spin effect in electrocatalysts. 2023. Available from: https://www.whxb.pku.edu.cn/EN/10.3866/PKU.WHXB202302049. [Last accessed on 21 Feb 2024]

[131]

He ZD,Eslamibidgoli MJ,Kowalski PM.Low-spin state of Fe in Fe-doped NiOOH electrocatalysts.Nat Commun2023;14:3498 PMCID:PMC10264450

[132]

Chen A,Zhou Z.Machine learning: accelerating materials development for energy storage and conversion.InfoMat2020;2:553-76

[133]

Zhai S,Cui P.A combined ionic Lewis acid descriptor and machine-learning approach to prediction of efficient oxygen reduction electrodes for ceramic fuel cells.Nat Energy2022;7:866-75