Solar-trackable super-wicking black metal panel for photothermal water sanitation

Singh, Subhash C.; ElKabbash, Mohamed; Li, Zilong; Li, Xiaohan; Regmi, Bhabesh; Madsen, Matthew; Jalil, Sohail A.; Zhan, Zhibing; Zhang, Jihua; Guo, Chunlei

Solar-trackable super-wicking black metal panel for photothermal water sanitation

Subhash C. Singh, Mohamed ElKabbash, Zilong Li, Xiaohan Li, Bhabesh Regmi, Matthew Madsen, Sohail A. Jalil, Zhibing Zhan, Jihua Zhang and Chunlei Guo ()
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Subhash C. Singh: University of Rochester
Mohamed ElKabbash: University of Rochester
Zilong Li: University of Rochester
Xiaohan Li: University of Rochester
Bhabesh Regmi: University of Rochester
Matthew Madsen: University of Rochester
Sohail A. Jalil: University of Rochester
Zhibing Zhan: University of Rochester
Jihua Zhang: University of Rochester
Chunlei Guo: University of Rochester

Nature Sustainability, 2020, vol. 3, issue 11, 938-946

Abstract: Abstract Solar-based water sanitation is an environmentally friendly process for obtaining clean water that requires efficient light-to-heat-to-vapour generation. Solar-driven interfacial evaporation has potential, but the inability to control interfacial evaporators for solar tracking limits efficiency at large solar zenith angles and when using optical concentration. Furthermore, clogging affects the efficiency of the device. Here, we create a super-wicking and super-light-absorbing (SWSA) aluminium surface for efficient solar-based water sanitation. The measured evaporation rate exceeds that of an ideal device operating at 100% efficiency, which we hypothesize resulted from a reduced enthalpy of vaporization within the microcapillaries. Limited solar absorber–water contact for water transport minimizes heat losses to bulk water and maximizes heat localization at the SWSA surface. The device can be mounted at any angle on a floating platform to optimize incident solar irradiance and can readily be integrated with commercial solar-thermal systems. With a design that is analogous to bifacial photovoltaic solar panels, we show a 150% increase in efficiency compared with a single-sided SWSA. Given the open capillary channels, the device surface can be easily cleaned and reused. Using the SWSA surface to purify contaminated water, we show a decrease in the level of contaminants to well below the WHO and EPA standards for drinkable water.

Date: 2020
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DOI: 10.1038/s41893-020-0566-x

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