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Main Authors: Agrawal, Nikhil R., Duan, Chao, Wang, Rui
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2212.00141
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author Agrawal, Nikhil R.
Duan, Chao
Wang, Rui
author_facet Agrawal, Nikhil R.
Duan, Chao
Wang, Rui
contents Understanding overcharging and charge inversion is one of the long-standing challenges in soft matter and biophysics. To study these phenomena, we employ the modified Gaussian renormalized fluctuation theory, which allows for the self-consistent accounting of spatially varying ionic strength, as well as the spatial variations in dielectric permittivity and excluded volume effects. The underlying dependence of overcharging on the electrostatic coupling is elucidated by varying surface charge, counterion valency, and dielectric contrast. Consistent with simulations, three characteristic regimes corresponding to weak, moderate, and strong coupling are identified. Important features like the inversion of zeta potential, crowding and ionic layering at the surface are successfully captured. For weak coupling, there is no overcharging. In the moderate coupling regime, overcharging increases with surface charge. Finally, in the strong coupling regime, ionic crowding and saturation in overcharging are observed. Our theory predicts non-monotonic dependence of charge inversion on multivalent salt concentration as well as the addition of monovalent salt, in quantitative agreement with experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2212_00141
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle On the nature of overcharging and charge inversion in electrical double layers
Agrawal, Nikhil R.
Duan, Chao
Wang, Rui
Soft Condensed Matter
Materials Science
Understanding overcharging and charge inversion is one of the long-standing challenges in soft matter and biophysics. To study these phenomena, we employ the modified Gaussian renormalized fluctuation theory, which allows for the self-consistent accounting of spatially varying ionic strength, as well as the spatial variations in dielectric permittivity and excluded volume effects. The underlying dependence of overcharging on the electrostatic coupling is elucidated by varying surface charge, counterion valency, and dielectric contrast. Consistent with simulations, three characteristic regimes corresponding to weak, moderate, and strong coupling are identified. Important features like the inversion of zeta potential, crowding and ionic layering at the surface are successfully captured. For weak coupling, there is no overcharging. In the moderate coupling regime, overcharging increases with surface charge. Finally, in the strong coupling regime, ionic crowding and saturation in overcharging are observed. Our theory predicts non-monotonic dependence of charge inversion on multivalent salt concentration as well as the addition of monovalent salt, in quantitative agreement with experiments.
title On the nature of overcharging and charge inversion in electrical double layers
topic Soft Condensed Matter
Materials Science
url https://arxiv.org/abs/2212.00141