(419h) A Kinetic Model for CO2 Capture By Lithium Silicates

Lithium-based ceramics, notably lithium orthosilicate, Li₄SiO₄, have been evaluated as potential CO₂ sorbents for sorption-enhanced WGS reactions. One challenge in developing faster, more efficient sorbents is the lack of adequate models to reduce kinetic data to physically meaningful parameters. Here, it is shown that a piece-wise fit of the Ishida and Wen core-shell model yields physically meaningful reaction rate constants and diffusion coefficients when applied to a series of three different Li₄SiO₄ samples: a citrate sol-gel prepared material, a material from a surfactant-mediated synthesis, and an annealed sample. All samples show an identical, 3-order of magnitude change in diffusivity (from ~10^-7 to ~10^-10 cm²/s) of the rate-limiting process as a function of conversion. We attribute the initial faster diffusion to facile movement of Li⁺ in the reactant Li₄SiO₄, which mediates the transport of O^2- between silicate and carbonate phases. The effective diffusivity drops with the growth of product in the reactant matrix with increasing average conversion. This result shows that our material synthesis modifications do not change the intrinsic diffusivity as a function of composition in these sorbent materials, and that changes in performance are only due to changes in diffusion path length. The novel methodology introduced here may have applicability in the analysis of other diffusion-reaction systems.