Water electrolysis

Arthur J. Shih; Mariana C.O. Monteiro; Federico Dattila; Davide Pavesi; Matthew Philips; Alisson H.M. da Silva; Rafaël E. Vos; Kasinath Ojha; Sunghak Park; Onno van der Heijden; Giulia Marcandalli; Akansha Goyal; Matias Villalba; Xiaoting Chen; G. T.Kasun Kalhara Gunasooriya; Ian McCrum; Rik Mom; Núria López; Marc T.M. Koper

doi:10.1038/s43586-022-00164-0

Water electrolysis

Arthur J. Shih^*
, Mariana C.O. Monteiro
, Federico Dattila
, Davide Pavesi
, Matthew Philips
, Alisson H.M. da Silva
, Rafaël E. Vos
, Kasinath Ojha
, Sunghak Park
, Onno van der Heijden
, Giulia Marcandalli
, Akansha Goyal
, Matias Villalba
, Xiaoting Chen
, G. T.Kasun Kalhara Gunasooriya^*
, Ian McCrum^*
, Rik Mom^*
, Núria López^*
, Marc T.M. Koper^*

^*Corresponding author for this work

Department of Physics

Northwestern University
Leiden University
Polytechnic University of Turin
Clarkson University
CSIC

Research output: Contribution to journal › Review › peer-review

Abstract

Electrochemistry has the potential to sustainably transform molecules with electrons supplied by renewable electricity. It is one of many solutions towards a more circular, sustainable and equitable society. To achieve this, collaboration between industry and research laboratories is a must. Atomistic understanding from fundamental experiments and modelling can be used to engineer optimized systems whereas limitations set by the scaled-up technology can direct the systems studied in the research laboratory. In this Primer, best practices to run clean laboratory-scale electrochemical systems and tips for the analysis of electrochemical data to improve accuracy and reproducibility are introduced. How characterization and modelling are indispensable in providing routes to garner further insights into atomistic and mechanistic details is discussed. Finally, important considerations regarding material and cell design for scaling up water electrolysis are highlighted and the role of hydrogen in our society’s energy transition is discussed. The future of electrochemistry is bright and major breakthroughs will come with rigour and improvements in the collection, analysis, benchmarking and reporting of electrochemical water splitting data.

Original language	English
Article number	84
Journal	Nature Reviews Methods Primers
Volume	2
Issue number	1
ISSN	2662-8449
DOIs	https://doi.org/10.1038/s43586-022-00164-0
Publication status	Published - 2022

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

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Shih, A. J., Monteiro, M. C. O., Dattila, F., Pavesi, D., Philips, M., da Silva, A. H. M., Vos, R. E., Ojha, K., Park, S., van der Heijden, O., Marcandalli, G., Goyal, A., Villalba, M., Chen, X., Gunasooriya, G. T. K. K., McCrum, I., Mom, R., López, N., & Koper, M. T. M. (2022). Water electrolysis. Nature Reviews Methods Primers, 2(1), Article 84. https://doi.org/10.1038/s43586-022-00164-0

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title = "Water electrolysis",

abstract = "Electrochemistry has the potential to sustainably transform molecules with electrons supplied by renewable electricity. It is one of many solutions towards a more circular, sustainable and equitable society. To achieve this, collaboration between industry and research laboratories is a must. Atomistic understanding from fundamental experiments and modelling can be used to engineer optimized systems whereas limitations set by the scaled-up technology can direct the systems studied in the research laboratory. In this Primer, best practices to run clean laboratory-scale electrochemical systems and tips for the analysis of electrochemical data to improve accuracy and reproducibility are introduced. How characterization and modelling are indispensable in providing routes to garner further insights into atomistic and mechanistic details is discussed. Finally, important considerations regarding material and cell design for scaling up water electrolysis are highlighted and the role of hydrogen in our society{\textquoteright}s energy transition is discussed. The future of electrochemistry is bright and major breakthroughs will come with rigour and improvements in the collection, analysis, benchmarking and reporting of electrochemical water splitting data.",

author = "Shih, \{Arthur J.\} and Monteiro, \{Mariana C.O.\} and Federico Dattila and Davide Pavesi and Matthew Philips and \{da Silva\}, \{Alisson H.M.\} and Vos, \{Rafa{\"e}l E.\} and Kasinath Ojha and Sunghak Park and \{van der Heijden\}, Onno and Giulia Marcandalli and Akansha Goyal and Matias Villalba and Xiaoting Chen and Gunasooriya, \{G. T.Kasun Kalhara\} and Ian McCrum and Rik Mom and N{\'u}ria L{\'o}pez and Koper, \{Marc T.M.\}",

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year = "2022",

doi = "10.1038/s43586-022-00164-0",

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volume = "2",

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TY - JOUR

T1 - Water electrolysis

AU - Shih, Arthur J.

AU - Monteiro, Mariana C.O.

AU - Dattila, Federico

AU - Pavesi, Davide

AU - Philips, Matthew

AU - da Silva, Alisson H.M.

AU - Vos, Rafaël E.

AU - Ojha, Kasinath

AU - Park, Sunghak

AU - van der Heijden, Onno

AU - Marcandalli, Giulia

AU - Goyal, Akansha

AU - Villalba, Matias

AU - Chen, Xiaoting

AU - Gunasooriya, G. T.Kasun Kalhara

AU - McCrum, Ian

AU - Mom, Rik

AU - López, Núria

AU - Koper, Marc T.M.

PY - 2022

Y1 - 2022

N2 - Electrochemistry has the potential to sustainably transform molecules with electrons supplied by renewable electricity. It is one of many solutions towards a more circular, sustainable and equitable society. To achieve this, collaboration between industry and research laboratories is a must. Atomistic understanding from fundamental experiments and modelling can be used to engineer optimized systems whereas limitations set by the scaled-up technology can direct the systems studied in the research laboratory. In this Primer, best practices to run clean laboratory-scale electrochemical systems and tips for the analysis of electrochemical data to improve accuracy and reproducibility are introduced. How characterization and modelling are indispensable in providing routes to garner further insights into atomistic and mechanistic details is discussed. Finally, important considerations regarding material and cell design for scaling up water electrolysis are highlighted and the role of hydrogen in our society’s energy transition is discussed. The future of electrochemistry is bright and major breakthroughs will come with rigour and improvements in the collection, analysis, benchmarking and reporting of electrochemical water splitting data.

AB - Electrochemistry has the potential to sustainably transform molecules with electrons supplied by renewable electricity. It is one of many solutions towards a more circular, sustainable and equitable society. To achieve this, collaboration between industry and research laboratories is a must. Atomistic understanding from fundamental experiments and modelling can be used to engineer optimized systems whereas limitations set by the scaled-up technology can direct the systems studied in the research laboratory. In this Primer, best practices to run clean laboratory-scale electrochemical systems and tips for the analysis of electrochemical data to improve accuracy and reproducibility are introduced. How characterization and modelling are indispensable in providing routes to garner further insights into atomistic and mechanistic details is discussed. Finally, important considerations regarding material and cell design for scaling up water electrolysis are highlighted and the role of hydrogen in our society’s energy transition is discussed. The future of electrochemistry is bright and major breakthroughs will come with rigour and improvements in the collection, analysis, benchmarking and reporting of electrochemical water splitting data.

U2 - 10.1038/s43586-022-00164-0

DO - 10.1038/s43586-022-00164-0

M3 - Review

AN - SCOPUS:85143837023

SN - 2662-8449

VL - 2

JO - Nature Reviews Methods Primers

JF - Nature Reviews Methods Primers

IS - 1

M1 - 84

ER -

Water electrolysis

Abstract

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