A scalable microstructure photonic coating fabricated by roll-to-roll “defects” for daytime sub-ambient passive radiation cooling

Liu, Sipan; Sui, Chenxi; Harbinson, Myers; Pudlo, Michael; Perera, Himendra; Zhang, Zhenzhen; Liu, Ruguan; Ku, Zahyun; Islam, Md Didarul; Liu, Yuxuan; Zhu, Yong; Genzer, Jan; Khan, Saad A.; Hsu, Po‐Chun; Ryu, Jihye

doi:10.26434/chemrxiv-2022-b1tm1

Cited by 1 publication

(1 citation statement)

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“…Radiative cooling is a key technology that reduces the temperature of sky-facing objects through radiative energy transfer between the objects and outer space at 3 K [1]. As a consequence of its prominent role, passive radiative cooling (PRC) has proven to be a promising electricity-free cooling strategy for dissipating heat of terrestrial objects through the atmospheric transparency window from 8 µm to 13 µm [2][3][4][5][6], and has attracted much attention for its potential of mitigating global warming [7] and the urban heat island effect [8]. Sub-ambient daytime cooling applications under direct sunlight illumination are particularly attractive and challenging to achieve [9,10].…”

Section: Introductionmentioning

confidence: 99%

Radiative cooling performance of a modified paint formulation with an integrated UV and convection shielding layer

Lio,

Levorin,

Erdogan

et al. 2024

Preprint

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Passive radiative cooling (PRC) technology promises to reduce a significant fraction of our energy needs and carbon footprint associated with cooling. Among different approaches, paint-like systems present several advantages in cost-effectiveness, scalability, and application ease. We report on a PRC system consisting of a paint mixture modified with 50 %wt glass bubbles and a top polypropylene-polyethylene-polypropylene (PP-PE-PP) film typically used as a battery separator. The resulting material exhibits a solar reflectance of 94 % and an absorption (evaluated by Attenuated Total Reflectance spectroscopy) with a peak at 10 µm of 60 %. The addition of the glass bubbles and the top film increases the paint reflectance over the solar spectrum and the UV, thanks to the nanoporous PP-PE-PP film (NPF), while allowing most thermal radiation through, shielding from convection, and making the coating more easily washable. The material has been tested under realistic outdoor conditions, checking the different performance obtained when sticking the PP-PE-PP film directly onto the wet paint layer or by using it as a separate windshield enclosing the sample test chamber. Despite its high solar reflectance, no radiative cooling is observed with respect to ambient temperature during the peak hours (solar irradiation >500 W m −2). Below this threshold, a temperature drop of −3 °C and a cooling power exceeding 100 W m−2 is observed. Notably, even using a visibly opaque convection shield, the configuration where the PP-PE-PP film seals the sample results in a substantial overheating of the air pocket surrounding the sample , which is detrimental to obtaining a temperature drop with respect to the true ambient temperature.

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