Simulation of Water Vapor Sorption Profiles on Activated Carbons in the Context of the Nuclear Industry

Simulation of Water Vapor Sorption Profiles on Activated Carbons in the Context of the Nuclear Industry

Activated carbons (ACs) are employed in the nuclear industry to mitigate the emission of potential radioactive iodine species. Their retention performances towards iodine are mainly dependent on the relative humidity due to the competitive effect induced by adsorbed water molecules. Thus, this work...

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Bibliographic Details
Main Authors: Felipe Cabral Borges Martins, Mouheb Chebbi, Céline Monsanglant-Louvet, Bénoit Marcillaud, Audrey Roynette
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Separations
Subjects:
adsorption
breakthrough curves
equilibrium
Klotz equation
kinetics
LDF model
Online Access:https://www.mdpi.com/2297-8739/12/5/126
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Summary:Activated carbons (ACs) are employed in the nuclear industry to mitigate the emission of potential radioactive iodine species. Their retention performances towards iodine are mainly dependent on the relative humidity due to the competitive effect induced by adsorbed water molecules. Thus, this work will focus on the prediction of AC behavior toward the capture of water vapor to better assess the poisoning effect on radiotoxic iodine removal. For the first time, H<sub>2</sub>O breakthrough curves (BTCs) on nuclear grade ACs are predicted through a specific methodology based on the combination of transport phenomena with adsorption kinetics and equilibrium. Three ACs, similar to those deployed in the nuclear context, are considered within the present study. Our model is based on the Linear Driving Force Model (LDF), governed by an intraparticle diffusion mechanism, notably surface and Knudsen diffusions. In addition, the type V isotherms obtained for H<sub>2</sub>O and the investigated carbon supports were described through the Klotz equation, taking into account the formation and progressive growth of H<sub>2</sub>O clusters within the internal porosity. This methodology allowed us to successfully simulate the H<sub>2</sub>O adsorption by a non-impregnated AC, where only physisorption phenomena are involved. In addition, promising results were highlighted when extrapolating to the two other impregnated ACs (AC 5KI and AC Nuclear).
ISSN:2297-8739

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