Spectrum Selective Interfaces and Materials towards Non-photothermal Saltwater Evaporation: Demonstration with a White Ceramic Wick

TL;DR

This paper demonstrates a spectrum-selective, light-driven saltwater evaporation method using a white aluminum nitride wick, offering a low-cost, energy-efficient alternative to traditional photothermal desalination.

Contribution

It introduces a novel non-photothermal desalination approach utilizing deep-UV interactions with white ceramic materials, diverging from conventional black photothermal methods.

Findings

Light enhances evaporation via spectrum-selective interactions.

Aluminum nitride wicks enable salt-water bond targeting.

Potential for low-cost, low-energy desalination technologies.

Abstract

Most solar desalination efforts are photothermal: they evaporate water with ``black'' materials that absorb as much sunlight as possible. Such ``brine-boiling'' methods are limited by the high thermal mass of water, i.e., its capacity to store and release heat. Here, we study the light-enhanced evaporation by a hard, white, aluminum nitride wick, and propose a route to selectively target salt-water bonds instead of bulk heating via deep-UV interactions. Through experiments and analyses that isolate the effects of light absorption and heating in aluminum nitride, we provide experimental evidence of a light-driven, spectrum-selective path to non-photothermal saltwater evaporation. Leverage of these light-matter interactions in white ceramic wicks may achieve low-cost, low-energy desalination, reduce the heat island effects of traditional solar technologies, and contribute to future cooling technologies where drought is also a concern.