Multifunctional Roles of Clathrate Hydrates Nanoreactors for CO2 Reduction

Multifunctional Roles of Clathrate Hydrates Nanoreactors for CO2 Reduction

In this study, we explore a possible platform for the CO2 reduction (CO2R) in one of water's solid phases, namely clathrate hydrates (CHs), by ab initio molecular dynamics and well-tempered metadynamics simulations with periodic boundary conditions. We find that the stacked H2O nanocages in CHs...

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Bibliographic Details
Published in:Chemistry : a European journal p. e202302253
Main Authors: Huang, Haibei, Xue, Lijuan, Bu, Yuxiang
Format: Journal Article
Language:English
Published: Germany 14-08-2023
Subjects:
multifunction characteristics
CO2 reduction
ab initio molecular dynamics simulation
Nanoreactor
clathrate hydrate
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Summary:In this study, we explore a possible platform for the CO2 reduction (CO2R) in one of water's solid phases, namely clathrate hydrates (CHs), by ab initio molecular dynamics and well-tempered metadynamics simulations with periodic boundary conditions. We find that the stacked H2O nanocages in CHs assist to initialize CO2R by increasing the electron-binding ability of CO2. The substantial CO2R processes are further influenced by the hydrogen bond (H-bond) networks in CHs. The first intermediate CO2- in this process can be stabilized through cage structure reorganization into the H-bonded [CO2-···H-OHcage] complex. Further cooperative structural dynamics enables the complex to convert into a vital transient [CO22-···H-OHcage] intermediate via a low-barrier disproportionation-like process. Such a highly reactive intermediate spontaneously triggers sequent double proton transfer along its tethering H-bonds, finally converting it into HCOOH. These hydrogen-bonded nanoreactors feature multifunction in facilitating CO2R such as confining, tethering, H-bond catalyzing and proton pump. Our findings have a general interest and extend the knowledge of CO2R into porous aqueous systems.
ISSN:1521-3765