Litcius/Paper detail

Polyzwitterionic hydrogel using waste biomass as solar absorbent for efficient evaporation in high salinity brine

Wenzong Liu, Sihui Wang, Zhenglin Chen, Jiaqi Yang, Zhiling Li, Aijie Wang

2024Green Carbon19 citationsDOIOpen Access PDF

Abstract

Solar-driven interfacial vapor generation (SVG) is a promising strategy for brine purification. However, the effective combination of functional evaporator backbones and solar absorbers for SVG enhancement remains challenging in high-salinity brines (≥ 10 wt%). Herein, a biomass-based polyzwitterionic hydrogel (PZH) was developed to improve the SVG performances in 10 wt% brine. Zwitterions with specific anti-polyelectrolyte effects served as backbones for accelerating H 2 O transportation, with fewer salt deposits and macropore channels. The biomass of straw prepared at a pyrolysis temperature at 600 ℃ was the most effective solar absorber. The synthesis of So600-PZH-8mm yielded the optimal solar evaporator with a low evaporation enthalpy of 877.79 J·g −1 , a remarkable solar-to-vapor energy efficiency of 87.1%, and a high evaporation rate of 3.57 kg·m −2 ·h −1 under 1 sun irradiation and a relative humidity of 30%. Multi-cycle evaporation tests further verified the high quality of the steam water, high salt resistance, reliability, and durability of So600-PZH-8mm in practical applications. Furthermore, density functional theory (DFT) calculations of the binding energies of charged groups and ions verified the anti-polyelectrolyte effect and swelling behavior of the PZHs. Overall, this study demonstrated the effectiveness of waste biomass as solar absorber for high-efficiency solar adsorption and water activation, which opens a new perspective to inspire the up-conversion of waste biomass in more valuable and meaningful ways. • Sorghum straw served as an effective solar absorbent in hydrogel evaporators. • The So600-PZH-8mm hydrogel reached a maximum evaporation rate of 3.57 kg·m -2 ·h -1 due to reduced energy requirement. • Salt ions would break DMAPS-DMAPS and convert to DMAPS-Na + , leading to anti-polyelectrolyte effects of PZHs.

Topics & Concepts

BrineSalinityEnvironmental scienceEvaporationBiomass (ecology)Solar stillWaste managementPulp and paper industryEnvironmental engineeringMaterials scienceDesalinationChemistryGeologyEngineeringGeographyOceanographyMeteorologyBiochemistryOrganic chemistryMembraneSolar-Powered Water Purification MethodsSolar Thermal and Photovoltaic SystemsAdsorption and Cooling Systems