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All-day passive radiative cooling using common salts
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  • Mariana Desireé Reale Batista,
  • Alyssa Troksa,
  • Hannah Eshelman,
  • Michael Bagge-Hansen,
  • John Roehling
Mariana Desireé Reale Batista
Lawrence Livermore National Laboratory
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Alyssa Troksa
Lawrence Livermore National Laboratory
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Hannah Eshelman
Lawrence Livermore National Laboratory
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Michael Bagge-Hansen
Lawrence Livermore National Laboratory
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John Roehling
Lawrence Livermore National Laboratory

Corresponding Author:roehling1@llnl.gov

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Abstract

Radiative cooling materials continue to underperform compared to their theoretical potential due to parasitic heating from contact with ambient air. Solutions to this problem are expensive or complex to fabricate. Here, a potentially inexpensive, simply fabricated material that improves cooling performance by reducing parasitic heating was created using naturally abundant salts. NaCl and KCl are not typically considered for radiative cooling because of their high hygroscopicity and low mechanical strength; however, these compounds are highly infrared-transparent and can be fabricated into aerogel-like structures to provide thermally insulating properties. Salt aerogels, described herein, scattered (reflected) visible light, transmitted infrared radiation, and provided thermal insulation. They were packaged into mechanical supporting panels to avoid physical disruption and the nanostructure was stabilized to moisture by adding anti-caking agent. The panels were able to keep an underlying surface below ambient temperature for a full 24-hour cycle and reduced parasitic heating rate by more than half (compared to an uncovered surface). The panels were able to cool a variety of underlying surfaces, even highly absorbing surfaces that are normally well above ambient temperature during the day. This work demonstrates an affordable, easily produced, electricity-free cooling technology with potential to be manufactured for large-scale practical applications.
08 Mar 2023Submitted to Energy & Environmental Materials
10 Mar 2023Submission Checks Completed
10 Mar 2023Assigned to Editor
10 Mar 2023Review(s) Completed, Editorial Evaluation Pending
11 Mar 2023Reviewer(s) Assigned
26 Apr 2023Editorial Decision: Revise Minor