
2022 roadmap on low temperature electrochemical CO2 reduction
Author(s) -
Ifan E. L. Stephens,
Karen Chan,
Alexander Bagger,
Shan W. Boettcher,
Julien Bonin,
Etienne Boutin,
Aya K. Buckley,
Raffaella Buonsanti,
Etosha R. Cave,
Xiaoxia Chang,
See Wee Chee,
Alisson H. M. da Silva,
Phil De Luna,
Oliver Einsle,
Balázs Endrődi,
Marı́a Escudero-Escribano,
Jorge V. Ferreira de Araujo,
Marta Costa Figueiredo,
Christopher Hahn,
Kentaro U. Hansen,
Sophia Haussener,
Sara Hunegnaw,
Ziyang Huo,
Yun Jeong Hwang,
Csaba Janáky,
Buddhinie Srimali Jayathilake,
Feng Jiao,
Zarko P. Jovanov,
Parisa Karimi,
Marc T. M. Koper,
Kendra P. Kuhl,
Woong Hee Lee,
Zhiqin Liang,
Xuan Li,
Sichao Ma,
Ming Ma,
HyungSuk Oh,
Marc Robert,
Beatriz Roldán Cuenya,
Jan Rossmeisl,
Claudie Roy,
Mary P. Ryan,
Edward H. Sargent,
Paula SebastiánPascual,
Brian Seger,
Ludmilla Steier,
Peter Strasser,
Ana Sofía Varela,
Rafaël E. Vos,
Xue Wang,
Bingjun Xu,
Hossein Yadegari,
Yuxiang Zhou
Publication year - 2022
Publication title -
jphys energy
Language(s) - Uncategorized
Resource type - Journals
ISSN - 2515-7655
DOI - 10.1088/2515-7655/ac7823
Subject(s) - commercialization , electrochemical energy storage , renewable energy , benchmarking , electricity , nanotechnology , electrochemistry , scale (ratio) , process engineering , environmental economics , biochemical engineering , environmental science , materials science , engineering , business , chemistry , electrical engineering , physics , electrode , supercapacitor , economics , marketing , quantum mechanics