Proton exchange membrane fuel cells: application for value-added chemical productions

Xia Jiang; Rui Chen; Yan-Xin Chen; Can-Zhong Lu

doi:10.20517/cs.2023.44

Chemical Synthesis ›› 2024, Vol. 4 ›› Issue (1) :6 DOI: 10.20517/cs.2023.44

review-article

Proton exchange membrane fuel cells: application for value-added chemical productions

Xia Jiang ¹^,²
, Rui Chen ¹^,²
, Yan-Xin Chen ¹^,²^,^*
, Can-Zhong Lu ¹^,²^,^*

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Abstract

Proton exchange membrane fuel cells (PEMFCs) can be used as reactors to produce chemicals and co-generate electricity and chemicals. Their mild reaction conditions, high product selectivity, and energy utilization have profoundly impacted gas separation, water treatment, and energy utilization fields. Given the lack of systematic reports on the current research status of utilizing PEMFCs for chemical production and the co-production of electricity and chemicals, this article summarizes the types of reactions and catalyst usage involved in this multifaceted application. It analyzes how to improve the production and performance of the system from four aspects: electrolyte membranes, catalysts, assembly methods, and reaction processes. Finally, the article analyzes the current research shortcomings in utilizing PEMFCs for these applications and provides prospects for future development.

Keywords

PEMFCs / chemical production / co-generation of electricity / chemicals

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Xia Jiang, Rui Chen, Yan-Xin Chen, Can-Zhong Lu. Proton exchange membrane fuel cells: application for value-added chemical productions. Chemical Synthesis, 2024, 4(1): 6 DOI:10.20517/cs.2023.44

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References

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

[1]	Haider R,Ma ZF.High temperature proton exchange membrane fuel cells: progress in advanced materials and key technologies.Chem Soc Rev2021;50:1138-87

[2]	Wee JH.Applications of proton exchange membrane fuel cell systems.Renew Sustain Energy Rev2007;11:1720-38

[3]	Pan Z,An L.Alkaline anion exchange membrane fuel cells for cogeneration of electricity and valuable chemicals.J Power Sources2017;365:430-45

[4]	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

[5]	Liu S,Fu XZ.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

[6]	Antolini E.Low molecular weight alkane-fed solid oxide fuel cells for power and chemicals cogeneration.J Energy Chem2023;80:711-35

[7]	Alcaide F,Brillas E.Fuel cells for chemicals and energy cogeneration.J Power Sources2006;153:47-60

[8]	Heng Z,Yin Y.Fuel cells reactor for chemicals and electric energy cogeneration.J Electrochem2018;24:615-27

[9]	de Souza RFB, Florio DZ, Antolini E, Neto AO. Partial methane oxidation in fuel cell-type reactors for co-generation of energy and chemicals: a short review.Catalysts2022;12:217

[10]	Kishi R,Yoshida-Hirahara M,Yamanaka I.Green synthesis of methyl formate via electrolysis of pure methanol.ACS Sustain Chem Eng2020;8:11532-40

[11]	Rodríguez-Gómez A,de Lucas-consuegra A.Influence of Pt/Ru anodic ratio on the valorization of ethanol by PEM electrocatalytic reforming towards value-added products.J Energy Chem2021;56:264-75

[12]	Kawaguchi D,Kurokawa H.Upgrading of ethanol to 1,1-diethoxyethane by proton-exchange membrane electrolysis.ChemSusChem2021;14:4431-8

[13]	Rodríguez-gómez A,Sánchez P.Boosting hydrogen and chemicals production through ethanol electro-reforming on Pt-transition metal anodes.J Energy Chem2022;70:394-406

[14]	Lee B.Efficient and selective formation of methanol from methane in a fuel cell-type reactor.J Catal2011;279:233-40

[15]	Iguchi S,Hoshino R.Direct epoxidation of propylene with water at a PtO_x anode using a solid-polymer-electrolyte electrolysis cell.Catal Sci Technol2022;12:469-73

[16]	Yang CH,Li Y.Selective conversion of propane by electrothermal catalysis in proton exchange membrane fuel cell.ChemSusChem2023;e202300699

[17]	Kuramochi N,Ogihara H.Proton exchange membrane electrolysis of methanol for simultaneously synthesizing formaldehyde and hydrogen.Sustain Energy Fuels2023;7:778-85

[18]	Serrano-jiménez J,Rodríguez-gómez A,Romero A.Graphene-like materials as an alternative to carbon Vulcan support for the electrochemical reforming of ethanol: towards a complete optimization of the anodic catalyst.J Electroanal Chem2022;921:116680

[19]	Abdelnasser S,Ogihara H.Electrochemical oxidation of 1-propanol through proton exchange membrane electrolysis.J Electroanal Chem2023;928:117009

[20]	Abdelnasser S,Kurokawa H.Effect of nafion ionomer on proton exchange membrane electrolysis of benzyl alcohol.Chem Lett2023;52:560-3

[21]	Yi Y,Li G.A review on research progress in the direct synthesis of hydrogen peroxide from hydrogen and oxygen: noble-metal catalytic method, fuel-cell method and plasma method.Catal Sci Technol2016;6:1593-610

[22]	Gutiérrez-guerra N,Romero A,de Lucas-consuegra A.Electrocatalytic conversion of CO₂ to added-value chemicals in a high-temperature proton-exchange membrane reactor.Electrochem Commun2017;81:128-31

[23]	Ju HK,Kulkarni AP.Challenges and trends in developing technology for electrochemically reducing CO₂ in solid polymer electrolyte membrane reactors.J CO2 Util2019;32:178-86

[24]	Garcia LMS,Chair K.Methanol electrosynthesis from CO₂ reduction reaction in polymer electrolyte reactors - fuel cell type using [6,6′-(2,2′-bipyridine-6,6′-diyl)bis(1,3,5-triazine-2,4-diamine)] (dinitrate-O) copper (II) complex.Mater Today Sustain2022;19:100177

[25]	Inami Y,Yamanaka I.Effects of carbon supports on Ru electrocatalysis for the electrohydrogenation of toluene to methylcyclohexane.Electrocatalysis2018;9:204-11

[26]	Inami Y,Nagamatsu S,Yamanaka I.Synergy of Ru and Ir in the electrohydrogenation of toluene to methylcyclohexane on a ketjenblack-supported Ru-Ir alloy cathode.ACS Catal2019;9:2448-57

[27]	Nogami S,Fukazawa A,Mitsushima S.Highly selective and efficient electrocatalytic semihydrogenation of diphenylacetylene in a PEM reactor with Pt-Pd alloy cathode catalysts.J Electrochem Soc2020;167:155506

[28]	Nogami S,Iguchi S.Mechanistic insights into the electrocatalytic hydrogenation of alkynes on Pt-Pd electrocatalysts in a proton-exchange membrane reactor.ACS Catal2022;12:5430-40

[29]	Fukazawa A,Shida N.Electrocatalytic hydrogenation of benzoic acids in a proton-exchange membrane reactor.Org Biomol Chem2021;19:7363-8

[30]	Mitsudo K,Niki Y,Suga S.Electrochemical hydrogenation of enones using a proton-exchange membrane reactor: selectivity and utility.Beilstein J Org Chem2022;18:1055-61 PMCID:PMC9443409

[31]	Shimizu Y,Fukazawa A.Diastereoselective electrocatalytic hydrogenation of cyclic ketones using a proton-exchange membrane reactor: a step toward the electrification of fine-chemical production.ACS Energy Lett2023;8:1010-7

[32]	Nandenha J,Silva LMG,Neto AO.Partial oxidation of methane and generation of electricity using a PEMFC.Ionics2019;25:5077-82

[33]	Coelho JF,Gutierrez IM.Methane-to-methanol conversion and power co-generation on palladium: nickel supported on antimony tin oxide catalysts in a polymeric electrolyte reactor-fuel cell (PER-FC).Res Chem Intermed2022;48:5155-68

[34]	Li W,Gyenge E.Design of bifunctional electrodes for co-generation of electrical power and hydrogen peroxide.J Appl Electrochem2018;48:985-93

[35]	Yuan XZ,Jiang QZ.Cogeneration of cyclohexylamine and electrical power using PEM fuel cell reactor.Electrochem Commun2001;3:599-602

[36]	Buzzo G,De Souza R.Synthesis of hydroquinone with co-generation of electricity from phenol aqueous solution in a proton exchange membrane fuel cell reactor.Catal Commun2015;59:113-5

[37]	Ahmed S,Zhang H.Review on chitosan and two-dimensional MoS₂-based proton exchange membrane for fuel cell application: advances and perspectives.Energy Fuels2023;37:1699-730

[38]	Meyer Q,Cheng Y.Overcoming the electrode challenges of high-temperature proton exchange membrane fuel cells.Electrochem Energy Rev2023;6:16

[39]	Cha JE,Hwang J,Choi YW.Fuel cell performance improvement via the steric effect of a hydrocarbon-based binder for cathode in proton exchange membrane fuel cells.Sci Rep2022;12:14001 PMCID:PMC9386007

[40]	Liu M,Kong Y.The role of ionomers in the electrolyte management of zero-gap MEA-based CO₂ electrolysers: a Fumion vs. Nafion comparison.Appl Catal B Environ2023;335:122885

[41]	Wang L,Chen YX.Enhanced electro-oxidation of alcohols at electrochemically treated polycrystalline palladium surface.J Power Sources2013;242:872-6

[42]	Zaman S,Liu H.Carbon-based catalyst supports for oxygen reduction in proton-exchange membrane fuel cells.Trends Chem2022;4:886-906

[43]	Rodríguez-gómez A,Dorado F,Lopez-salas N.Efficient ethanol electro-reforming on bimetallic anodes supported on adenine-based noble carbons: hydrogen production and value-added chemicals.Mater Today Energy2023;32:101231

[44]	Zhao J,Li X.Structure, property, and performance of catalyst layers in proton exchange membrane fuel cells.Electrochem Energ Rev2023;6:13 PMCID:PMC10050052

[45]	Rodríguez-gómez A,de Lucas-consuegra A.Influence of the GDL and assembly mode of a PEM cell on the ethanol revalorization into chemicals.Chem Eng J2020;402:125298

[46]	Yamanaka I,Hashimoto T.A fuel-cell reactor for the direct synthesis of hydrogen peroxide alkaline solutions from H₂ and O₂.ChemSusChem2011;4:494-501

[47]	Oh LS,Lim E,Kim HJ.PtCu nanoparticle catalyst for electrocatalytic glycerol oxidation: how does the PtCu affect to glycerol oxidation reaction performance by changing pH conditions?.Catalysts2023;13:892

[48]	Rodríguez-gómez A,de Lucas-consuegra A.Additional pathways for the ethanol electro-reforming knowledge: the role of the initial concentration on the product yields.Fuel Process Technol2021;222:106954