Revealing the Active Phase of Copper during the Electroreduction
of CO2 in Aqueous Electrolyte by Correlating In
Situ X‑ray Spectroscopy and In Situ Electron Microscopy
posted on 2020-06-03, 20:04authored byJuan-Jesus Velasco-Velez, Rik V. Mom, Luis-Ernesto Sandoval-Diaz, Lorenz J. Falling, Cheng-Hao Chuang, Dunfeng Gao, Travis E. Jones, Qingjun Zhu, Rosa Arrigo, Beatriz Roldan Cuenya, Axel Knop-Gericke, Thomas Lunkenbein, Robert Schlögl
The
variation in the morphology and electronic structure of copper
during the electroreduction of CO2 into valuable hydrocarbons
and alcohols was revealed by combining in situ surface-
and bulk-sensitive X-ray spectroscopies with electrochemical scanning
electron microscopy. These experiments proved that the electrified
interface surface and near-surface are dominated by reduced copper.
The selectivity to the formation of the key C–C bond is enhanced
at higher cathodic potentials as a consequence of increased copper
metallicity. In addition, the reduction of the copper oxide electrode
and oxygen loss in the lattice reconstructs the electrode to yield
a rougher surface with more uncoordinated sites, which controls the
dissociation barrier of water and CO2. Thus, according
to these results, copper oxide species can only be stabilized kinetically
under CO2 reduction reaction conditions.