posted on 2022-10-06, 01:44authored byShuai Peng, Longqian Xu, Shihai Deng, Yunfeng Mao, Zhenyu Zhao, Deli Wu
The solar-driven evaporation technology provides a green
alternative
for solving water scarcity. However, it remains challenging to improve
the steam conversion efficiency due to the difficulties in simultaneously
coordinating light absorbance, water regulation, and thermal management
for broadband solar evaporators. Here, an unconventional solar evaporative
modulator materialultra-interfacial adherent dimethyl sulfoxide
polyvinyl alcohol (DMSO–PVA) hydrogel (DPH) was presented.
The material is based on the regulation of the PVA–PVA intra-
and PVA–water interchain hydrogen bonds by DMSO, which established
an adaptive high-cross-linking and homogeneous network. The consequent
ultra-thin hydrogel exploited an insulating polymer backbone and intracavity
hydration domain to simultaneously improve the light absorption and
thermal localization and activate the water molecule. As a proof-of-concept,
under 1 sun illumination (1 kW m–2), a DPH-based
graphene fiber membrane [ultra-thin hydrogel membrane (UHM)] achieved
97% light absorption, 2.33 kg m–2 h–1 water evaporation, and high salt-resistant evaporation (1.48 kg
m–2 h–1 under 25 wt % brine).
Compared to the pure graphene membrane, UHM increased the vaporization
by 64%, decreased the heat diffusion by over 14-folds, and reduced
the environmental heat loss by 2.6-folds. DPH possesses scalability
and versatility in bridging nanoscale photothermal materials and solar
evaporator geometric architecture and will facilitate the possibility
of advanced solar thermal applications.