A Molecularly Engineered Zwitterionic Hydrogel with Strengthened Anti‐Polyelectrolyte Effect: from High‐Rate Solar Desalination to Efficient Electricity Generation

Abstract Polyzwitterionic hydrogel is an emerging material for solar‐driven water evaporation in saline environment due to its special anti‐polyelectrolyte effect, which is a promising approach to co‐generation of freshwater and electricity. However, the molecular impact on anti‐polyelectrolyte effe...

Full description

Saved in:
Bibliographic Details
Published inAdvanced functional materials Vol. 33; no. 43
Main Authors Zheng, Si Yu, Zhou, Jiahui, Si, Mengjie, Wang, Shuaibing, Zhu, Fengbo, Lin, Ji, Fu, Jimin, Zhang, Dong, Yang, Jintao
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 18.10.2023
Subjects
Brines
Desalination
Electricity
Enthalpy
Evaporation rate
Hydrogels
Imidazole
Materials science
Microorganisms
Polyelectrolytes
Saline environments
Saline water
Seawater
Zwitterions
Online AccessGet full text

Cover

More Information
Summary:Abstract Polyzwitterionic hydrogel is an emerging material for solar‐driven water evaporation in saline environment due to its special anti‐polyelectrolyte effect, which is a promising approach to co‐generation of freshwater and electricity. However, the molecular impact on anti‐polyelectrolyte effect remains unclear, let alone to optimize the zwitterionic structure to promote water evaporation efficiency in high‐salinity brine. Herein, a molecularly engineered zwitterionic hydrogel is developed and the incorporated phenyl‐methylene‐imidazole motif greatly enhances the salt binding ability and strengthens anti‐polyelectrolyte effect, leading to boosted hydration, improved salt tolerance, ultra‐low evaporation enthalpy (almost half of traditional zwitterionic gel), and durable anti‐microbial ability in brine. Besides, gradient solar‐thermal network is penetrated to optimize water transport channel and heat confinement. The gel exhibits excellent evaporation rate of 3.17 kg m −2 h −1 in seawater, which is 1.6 times of that in water and such high efficiency could be maintained during 8 h continuous desalination, demonstrating outstanding salt tolerance. The high flux of ion stream can generate considerable voltage (321.3 mV) simultaneously. This work will bring new insights to the understanding of anti‐polyelectrolyte effect at molecular level and promote materials design for saline water evaporation.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202303272