Clay
minerals can adsorb large amounts of CO2 and are
present in anthropogenic storage sites for CO2. Nanoscale
functionalization of smectite clay minerals is essential for developing
technologies for carbon sequestration based on these materials and
for safe-guarding relevant long-term carbon storage sites. We investigate
the adsorption mechanisms of CO2 in dried and hydrated
synthetic Ni-exchanged fluorohectorite clayusing a combination
of powder X-ray diffraction, Raman spectroscopy, and inelastic neutron
scattering. Both dried and hydrated Ni-exchanged fluorohectorite show
crystalline swelling and spectroscopic changes in response to CO2 exposure. These changes can be attributed to interactions
with [Ni(OH)0.83(H2O)1.17]0.37
1.17+-interlayer species, and swelling occurs solely in
the interlayers where this condensed species is present. The experimental
conclusions are supported by density functional theory simulations.
This work demonstrates a hitherto overlooked important mechanism,
where a hydrogenous species present in the nanospace of a clay mineral
creates sorption sites for CO2.
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