CO₂ capture modeling using heat-activated serpentinite slurries

Oliver, Timothy K.; Farhang, Faezeh; Hodgins, Todd W.; Rayson, Mark S.; Brent, Geoff F.; Molloy, Thomas S.; Stockenhuber, Michael; Kennedy, Eric M.

Title: CO₂ capture modeling using heat-activated serpentinite slurries
Creator: Oliver, Timothy K.; Farhang, Faezeh; Hodgins, Todd W.; Rayson, Mark S.; Brent, Geoff F.; Molloy, Thomas S.; Stockenhuber, Michael; Kennedy, Eric M.
Relation: Energy & Fuels Vol. 33, Issue 3, p. 1753-1766
Publisher Link: http://dx.doi.org/10.1021/acs.energyfuels.8b02823
Publisher: American Chemical Society (ACS)
Resource Type: journal article
Date: 2019
Description: We present a model to describe carbon dioxide (CO₂) capture using reactive silicate-based mineral slurries exposed to a gas flow containing CO₂. The model is validated through experimentation using thermally conditioned or heat-activated serpentinite (hydrous metamorphic ultramafic rock) in a laboratory-scale bubble column reactor. The kinetic model developed advocates a holistic modeling approach, offering an expanded view of the dissolution of heat-activated serpentinite under lean CO₂ conditions, in which the gas–liquid–solid system and its influence on CO₂ dissolution and the coupled dissolution behavior of the material are considered in their entirety. Modeling incorporates the characteristics of the gas to liquid phase interaction, such as CO₂ composition of the gas phase and interfacial area, the composition of the aqueous phase and its temperature, and compositional and morphological features of the solid. We demonstrate that such an approach is essential when considering proton-limiting conditions that are especially relevant to mineral dissolution under dilute CO₂ conditions in short reaction timeframes. The model is of particular relevance to the use of reactive silicate-based minerals for the aqueous capture of CO₂ from dilute CO₂ gas streams. The model as developed can be used to predict CO₂ capture using heat-activated serpentinite slurries for a given set of operating conditions and should be adaptable for use with other alkaline materials of defined reactivity in similar or varying reaction settings by adequately specifying reaction conditions.
Subject: kinetic modeling; thermodynamic modeling; mass transfer; dissolution; minerals; SDG 13; Sustainable Development Goals
Identifier: http://hdl.handle.net/1959.13/1464103
Identifier: uon:46916
Identifier: ISSN:0887-0624
Language: eng
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