Sustainable, low-cost sorbents based on calcium chloride-loaded polyacrylamide hydrogels

TL;DR

This paper presents a novel, cost-effective hydrogel composite loaded with calcium chloride that efficiently captures atmospheric water, offering a sustainable alternative to existing sorbents for addressing water scarcity and energy challenges.

Contribution

The study introduces a new synthesis method for high-performance, low-cost calcium chloride-loaded polyacrylamide hydrogels with enhanced water absorption capabilities.

Findings

Achieves water uptakes of 0.92 g/g at 30% RH and 2.38 g/g at 70% RH.

Demonstrates stability over repeated sorption-desorption cycles.

Cost-performance ratio surpasses lithium chloride-based systems.

Abstract

Sorbents are promising materials for applications in atmospheric water harvesting, thermal energy storage, and passive cooling, thereby addressing central challenges related to water scarcity and the global energy transition. Recently, hygroscopic hydrogel composites have emerged as high-performance sorbents. However, many of these systems are fabricated with unsustainable and costly sorbent materials, which hinders their wide deployment. Here, the synthesis of high-performance, cost-efficient polyacrylamide hydrogels loaded with unprecedented amounts of calcium chloride is demonstrated. To this end, the swelling procedure of polyacrylamide hydrogels in aqueous calcium chloride solutions is optimized. The achievable salt loading in the hydrogel is characterized as a function of temperature, calcium chloride concentration in the swelling solution, and the hydrogel preparation conditions. The obtained hydrogel-salt composites are shown to be stable under repeated sorption-desorption cycling and enable water uptakes of 0.92 and 2.38 grams of water per gram of dry materials at 30% and 70% relative humidity, respectively. The resulting cost-performance ratio substantially exceeds lithium chloride-based systems. Further, the mechanistic insights on hydrogel salt interactions can guide the design of sustainable and low-cost sorbent materials for future applications in water and energy.