Kinetics of Sorption in Hygroscopic Hydrogels

Overview

Journal Nano Lett

Publisher American Chemical Society

Specialty Biotechnology

Date 2022 Jan 21

PMID 35061401

Authors

Carlos D Diaz-Marin

Lenan Zhang

Zhengmao Lu

Mohammed Alshrah

Jeffrey C Grossman

Evelyn N Wang

Affiliations

Soon will be listed here.

Abstract

Hygroscopic hydrogels hold significant promise for high-performance atmospheric water harvesting, passive cooling, and thermal management. However, a mechanistic understanding of the sorption kinetics of hygroscopic hydrogels remains elusive, impeding an optimized design and broad adoption. Here, we develop a generalized two-concentration model (TCM) to describe the sorption kinetics of hygroscopic hydrogels, where vapor transport in hydrogel micropores and liquid transport in polymer nanopores are coupled through the sorption at the interface. We show that the liquid transport due to the chemical potential gradient in the hydrogel plays an important role in the fast kinetics. The high water uptake is attributed to the expansion of hydrogel during liquid transport. Moreover, we identify key design parameters governing the kinetics, including the initial porosity, hydrogel thickness, and shear modulus. This work provides a generic framework of sorption kinetics, which bridges the knowledge gap between the fundamental transport and practical design of hygroscopic hydrogels.

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