| Literature DB >> 30113834 |
Dae-Hyun Nam1, Oleksandr S Bushuyev1, Jun Li1,2, Phil De Luna1,3, Ali Seifitokaldani1, Cao-Thang Dinh1, F Pelayo García de Arquer1, Yuhang Wang1, Zhiqin Liang1, Andrew H Proppe1,4, Chih Shan Tan1, Petar Todorović1, Osama Shekhah5, Christine M Gabardo2, Jea Woong Jo1, Jongmin Choi1, Min-Jae Choi1, Se-Woong Baek1, Junghwan Kim1, David Sinton2, Shana O Kelley4,6, Mohamed Eddaoudi5, Edward H Sargent1.
Abstract
The electrochemical carbon dioxide reduction reaction (CO2RR) produces diverse chemical species. Cu clusters with a judiciously controlled surface coordination number (CN) provide active sites that simultaneously optimize selectivity, activity, and efficiency for CO2RR. Here we report a strategy involving metal-organic framework (MOF)-regulated Cu cluster formation that shifts CO2 electroreduction toward multiple-carbon product generation. Specifically, we promoted undercoordinated sites during the formation of Cu clusters by controlling the structure of the Cu dimer, the precursor for Cu clusters. We distorted the symmetric paddle-wheel Cu dimer secondary building block of HKUST-1 to an asymmetric motif by separating adjacent benzene tricarboxylate moieties using thermal treatment. By varying materials processing conditions, we modulated the asymmetric local atomic structure, oxidation state and bonding strain of Cu dimers. Using electron paramagnetic resonance (EPR) and in situ X-ray absorption spectroscopy (XAS) experiments, we observed the formation of Cu clusters with low CN from distorted Cu dimers in HKUST-1 during CO2 electroreduction. These exhibited 45% C2H4 faradaic efficiency (FE), a record for MOF-derived Cu cluster catalysts. A structure-activity relationship was established wherein the tuning of the Cu-Cu CN in Cu clusters determines the CO2RR selectivity.Entities:
Year: 2018 PMID: 30113834 DOI: 10.1021/jacs.8b06407
Source DB: PubMed Journal: J Am Chem Soc ISSN: 0002-7863 Impact factor: 15.419