Panagiotis Papangelakis, Rui Kai Miao, Ruihu Lu, Hanqi Liu, Xi Wang, Adnan Ozden, Shijie Liu, Ning Sun, Colin P. O’Brien, Yongfeng Hu, Mohsen Shakouri, Qunfeng Xiao, Mengsha Li, Behrooz Khatir, Jianan Erick Huang, Yakun Wang, Yurou Celine Xiao, Feng Li, Ali Shayesteh Zeraati, Qiang Zhang, Pengyu Liu, Kevin Golovin, Jane Y. Howe, Hongyan Liang, Ziyun Wang, Jun Li, Edward H. Sargent, David Sinton
{"title":"Improving the SO2 tolerance of CO2 reduction electrocatalysts using a polymer/catalyst/ionomer heterojunction design","authors":"Panagiotis Papangelakis, Rui Kai Miao, Ruihu Lu, Hanqi Liu, Xi Wang, Adnan Ozden, Shijie Liu, Ning Sun, Colin P. O’Brien, Yongfeng Hu, Mohsen Shakouri, Qunfeng Xiao, Mengsha Li, Behrooz Khatir, Jianan Erick Huang, Yakun Wang, Yurou Celine Xiao, Feng Li, Ali Shayesteh Zeraati, Qiang Zhang, Pengyu Liu, Kevin Golovin, Jane Y. Howe, Hongyan Liang, Ziyun Wang, Jun Li, Edward H. Sargent, David Sinton","doi":"10.1038/s41560-024-01577-9","DOIUrl":null,"url":null,"abstract":"The high concentrations of CO2 in industrial flue gases make these point sources attractive candidates for renewably powered electrocatalytic conversion of CO2 to products. However, trace SO2 in common flue gases rapidly and irreversibly poisons catalysts. Here we report that limiting hydrogen adsorption in the vicinity of electrochemically active sites deactivates SO2 to enable efficient CO2 conversion. We realize this approach via a polymer/catalyst/ionomer heterojunction design with combined hydrophobic and highly charged hydrophilic domains that diminish hydrogen adsorption and promote CO2 over SO2 transport. We develop an SO2-tolerant system that maintains ~50% faradaic efficiency towards multi-carbon products for over 150 h (at 100 mA cm–2). Extending this strategy to a high-surface-area composite catalyst, we achieve faradaic efficiencies of 84%, partial current densities of up to 790 mA cm–2 and energy efficiencies of ~25% towards multi-carbon products with a CO2 stream containing 400 ppm SO2, a performance that is competitive with the best reports using pure CO2. While the high concentration of CO2 in flue gas makes it an attractive feedstock for electrocatalytic production of useful molecules, SO2 contaminants can poison catalysts. Here the authors report a polymer/catalyst/ionomer heterojunction design with hydrophobic and hydrophilic domains that improves the SO2 tolerance of a Cu catalyst.","PeriodicalId":19073,"journal":{"name":"Nature Energy","volume":"9 8","pages":"1011-1020"},"PeriodicalIF":49.7000,"publicationDate":"2024-07-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Nature Energy","FirstCategoryId":"88","ListUrlMain":"https://www.nature.com/articles/s41560-024-01577-9","RegionNum":1,"RegionCategory":"材料科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENERGY & FUELS","Score":null,"Total":0}
引用次数: 0
Abstract
The high concentrations of CO2 in industrial flue gases make these point sources attractive candidates for renewably powered electrocatalytic conversion of CO2 to products. However, trace SO2 in common flue gases rapidly and irreversibly poisons catalysts. Here we report that limiting hydrogen adsorption in the vicinity of electrochemically active sites deactivates SO2 to enable efficient CO2 conversion. We realize this approach via a polymer/catalyst/ionomer heterojunction design with combined hydrophobic and highly charged hydrophilic domains that diminish hydrogen adsorption and promote CO2 over SO2 transport. We develop an SO2-tolerant system that maintains ~50% faradaic efficiency towards multi-carbon products for over 150 h (at 100 mA cm–2). Extending this strategy to a high-surface-area composite catalyst, we achieve faradaic efficiencies of 84%, partial current densities of up to 790 mA cm–2 and energy efficiencies of ~25% towards multi-carbon products with a CO2 stream containing 400 ppm SO2, a performance that is competitive with the best reports using pure CO2. While the high concentration of CO2 in flue gas makes it an attractive feedstock for electrocatalytic production of useful molecules, SO2 contaminants can poison catalysts. Here the authors report a polymer/catalyst/ionomer heterojunction design with hydrophobic and hydrophilic domains that improves the SO2 tolerance of a Cu catalyst.
Nature EnergyEnergy-Energy Engineering and Power Technology
CiteScore
75.10
自引率
1.10%
发文量
193
期刊介绍:
Nature Energy is a monthly, online-only journal committed to showcasing the most impactful research on energy, covering everything from its generation and distribution to the societal implications of energy technologies and policies.
With a focus on exploring all facets of the ongoing energy discourse, Nature Energy delves into topics such as energy generation, storage, distribution, management, and the societal impacts of energy technologies and policies. Emphasizing studies that push the boundaries of knowledge and contribute to the development of next-generation solutions, the journal serves as a platform for the exchange of ideas among stakeholders at the forefront of the energy sector.
Maintaining the hallmark standards of the Nature brand, Nature Energy boasts a dedicated team of professional editors, a rigorous peer-review process, meticulous copy-editing and production, rapid publication times, and editorial independence.
In addition to original research articles, Nature Energy also publishes a range of content types, including Comments, Perspectives, Reviews, News & Views, Features, and Correspondence, covering a diverse array of disciplines relevant to the field of energy.