Plausible photomolecular effect leading to water evaporation exceeding the thermal limit
Author(s)
Tu, Yaodong; Zhou, Jiawei; Lin, Shaoting; Alshrah, Mohammed; Zhao, Xuanhe; Chen, Gang; ... Show more Show less
DownloadPublished version (3.380Mb)
Publisher with Creative Commons License
Publisher with Creative Commons License
Creative Commons Attribution
Terms of use
Metadata
Show full item recordAbstract
We report in this work several unexpected experimental observations on evaporation from hydrogels under visible light illumination. 1) Partially wetted hydrogels become absorbing in the visible spectral range, where the absorption by both the water and the hydrogel materials is negligible. 2) Illumination of hydrogel under solar or visible-spectrum light-emitting diode leads to evaporation rates exceeding the thermal evaporation limit, even in hydrogels without additional absorbers. 3) The evaporation rates are wavelength dependent, peaking at 520 nm. 4) Temperature of the vapor phase becomes cooler under light illumination and shows a flat region due to breaking-up of the clusters that saturates air. And 5) vapor phase transmission spectra under light show new features and peak shifts. We interpret these observations by introducing the hypothesis that photons in the visible spectrum can cleave water clusters off surfaces due to large electrical field gradients and quadrupole force on molecular clusters. We call the light-induced evaporation process the photomolecular effect. The photomolecular evaporation might be happening widely in nature, potentially impacting climate and plants’ growth, and can be exploited for clean water and energy technologies.
Date issued
2023-11-07Department
Massachusetts Institute of Technology. Department of Mechanical EngineeringJournal
Proceedings of the National Academy of Sciences
Publisher
Proceedings of the National Academy of Sciences
Citation
Tu, Yaodong, Zhou, Jiawei, Lin, Shaoting, Alshrah, Mohammed, Zhao, Xuanhe et al. 2023. "Plausible photomolecular effect leading to water evaporation exceeding the thermal limit." Proceedings of the National Academy of Sciences, 120 (45).
Version: Final published version