A nonlinear attachment-detachment model with adsorption hysteresis for suspension-colloidal transport in porous media

A nonlinear attachment-detachment model with adsorption hysteresis for suspension-colloidal transport in porous media

•A nonlinear attachment-detachment model with hysteresis is proposed.•Introducing scanning desorption isotherms to model the deposition effect.•Static deposition and pulse injection tests are utilized to calibrate the parameters. In this study, we propose a nonlinear attachment-detachment model with...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) Vol. 578; p. 124080
Main Authors: Bai, Bing, Rao, Dengyu, Chang, Tao, Guo, Zhiguang
Format: Journal Article
Language:English
Published: Elsevier B.V 01-11-2019
Subjects:
Attachment-detachment model
Hysteretic effect
Nonlinear process
Unsteady flow
Variable concentration
Attachment-detachment model
Hysteretic effect
Unsteady flow
Nonlinear process
Variable concentration
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Summary:•A nonlinear attachment-detachment model with hysteresis is proposed.•Introducing scanning desorption isotherms to model the deposition effect.•Static deposition and pulse injection tests are utilized to calibrate the parameters. In this study, we propose a nonlinear attachment-detachment model with hysteresis for the transport of suspension-colloidal particles (SPs) in porous media. The proposed model uses an adsorption function and scanning desorption isotherms to model the deposition process of SPs. This model shows that increasing or decreasing the seepage velocity results in substantial changes in the penetration concentration of SPs, which is closely related to the adsorption hysteresis and the deposition dynamics of SPs. Studies show that previous linear attachment-detachment models probably result in an overestimation of the adsorption capacity of porous media. Static deposition tests and dynamic transport experiments using pulse injection were performed to calibrate the transport parameters. The effects of the seepage velocity, injection concentration and particle size on the transport parameters and reaction rate constant were investigated. Experiments were also performed under variable injection concentrations and seepage velocities. The results show that there is good agreement between the simulated and experimental breakthrough curves (BTCs).
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2019.124080