Back to Search Start Over

Airflow Enhanced Solar Evaporation Based on Janus Graphene Membranes with Stable Interfacial Floatability.

Authors :
Han DD
Chen ZD
Li JC
Mao JW
Jiao ZZ
Wang W
Zhang W
Zhang YL
Sun HB
Source :
ACS applied materials & interfaces [ACS Appl Mater Interfaces] 2020 Jun 03; Vol. 12 (22), pp. 25435-25443. Date of Electronic Publication: 2020 May 22.
Publication Year :
2020

Abstract

Solar interfacial evaporation has been recognized as a versatile energy conversion protocol for cutting-edge applications such as water treatment and power generation (e.g., hydro voltaic effect). Recently, to enhance water evaporation rates, water temperature and evaporation area have been considered as essential ingredients, and thus photothermal materials and three-dimensional hierarchical structures have been developed to promote light-to-heat conversion efficiency and enhance interfacial evaporation. However, less attention has been paid to the airflow effect, because the interfacial floatability of photothermal membranes should be considered under air blast. Here, inspired from the stable interfacial floatability of lotus leaves, we report the airflow enhanced solar interfacial evaporation approach using a graphene-based Janus membrane. Laser-induced graphene (LIG) film was treated unilaterally by O <subscript>2</subscript> plasma, forming a LIG/oxidized LIG (LIG-O) Janus membrane with distinct wettability on two sides. Higher water evaporation rate of 1.512 kg m <superscript>-2</superscript> h <superscript>-1</superscript> is achieved. The high solar interfacial evaporation performance can be attributed to the two advantages: (i) the combination of microscale capillary water transporting and nanoscale light trapping; (ii) hydrophobic/hydrophilic Janus membrane for stable interfacial floatability under airflow. Our approach is feasible for developing high-performance solar interfacial evaporation devices for practical clean energy utilization.

Details

Language :
English
ISSN :
1944-8252
Volume :
12
Issue :
22
Database :
MEDLINE
Journal :
ACS applied materials & interfaces
Publication Type :
Academic Journal
Accession number :
32401489
Full Text :
https://doi.org/10.1021/acsami.0c05401