posted on 2020-01-06, 12:39authored byJun Hyuk Kim, Zhao-Ying Chern, Seonyoung Yoo, Ben deGlee, Jenghan Wang, Meilin Liu
While
several proton-conducting anode materials have shown excellent tolerance
to sulfur poisoning, the mechanism is still unclear due largely to
the inability to probe miniscule amounts of sulfur-containing species
using conventional surface characterization techniques. Here we present
our findings in unraveling the mechanism of water-mediated sulfur
tolerance of a proton conductor under operating conditions empowered
by surface-sensitive, operando surface-enhanced Raman spectroscopy
(SERS) coupled with impedance spectroscopy. Contrary to the conventional
view that surface-adsorbed sulfur is removed mainly by oxygen anions,
it is found that −SO4 groups on the surface of the
proton conductor are converted to SO2 by a water-mediated
process, as confirmed by operando SERS analysis and density functional
theory (DFT)-based calculations. The combination of operando SERS
performed on a model electrode and theoretical computation offers
an effective approach to investigate into complex mechanisms of electrode
processes in various electrochemical systems, providing information
vital to achieve the rational design of better electrode materials.