posted on 2022-07-13, 15:13authored byKai Cui, Sankar Nair, David S. Sholl, J. R. Schmidt
Understanding the degradation of nanoporous materials
under exposure
to common acid gas contaminants (e.g., SO2, CO2, NO2, and H2S) is essential to elongate their
lifetime and thus enable their practical applications in separations
and catalysis. Previous theoretical investigations have focused on
the formation of isolated point defects, which are insufficient to
provide direct insights into the long-term evolution of the bulk properties
of materials such as zeolitic imidazolate frameworks (ZIFs) under
sustained acid gas exposure. To bridge this divide in both length
and time scales, we developed a first-principles lattice-based kinetic
model to simulate the defect propagation and bulk material breakdown
in ZIFs. This model closely reproduces the experimentally measured
macroscopic evolution of the time-dependent bulk materials proprieties
and also yields important new insights regarding the autocatalytic
nature of ZIF degradation and the spatial distribution of defects.
Our results suggest new experimental directions to identify nascent
defect clusters in degraded ZIFs and avenues to mitigate degradation
under challenging conditions of acid gas exposure.