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Main Author: Chen, Gang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.15121
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author Chen, Gang
author_facet Chen, Gang
contents Cloud absorption is acknowledged as the biggest source of uncertainty in the climate models. For over 70 years, many experiments have reported clouds absorbing more solar radiation than theory could predict. In the visible spectrum, simulations based on optical constants of water lead to negligible cloud absorption. This result had been explored by some experimentalists to calibrate the cloud absorption measurements. However, the author and his collaborators recently discovered that visible light can directly cleave off water molecular clusters at liquid-air interfaces (PNAS, e2312751120, 2023; e2320844121, 2024), which is named the photomolecular effect in analogy to the photoelectric effect. This discovery suggests that a crucial piece of physics has been missing in the existing theories: light can be absorbed at water-air interface. The photomolecular effect can be simulated by generalizing the boundary conditions for the Maxwell equations using Feibelman parameters that were derived in the past research on the surface photoelectric effect and surface plasmons. In this work, the author uses simulation to show that including the photomolecular effect at the air-water interface can potentially explain the cloud absorption anomaly. Although the lack of accurate Feibelman parameter values prevents a direct comparison of the current theory with experiments, this work points to an unexplored mechanism for explaining the cloud absorption anomaly and calls for further investigation on the impacts of photomolecular effect in the climate modeling.
format Preprint
id arxiv_https___arxiv_org_abs_2502_15121
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Photomolecular Effect as A Potential Explanation for The Cloud Absorption Anomaly
Chen, Gang
Atmospheric and Oceanic Physics
Applied Physics
Optics
Cloud absorption is acknowledged as the biggest source of uncertainty in the climate models. For over 70 years, many experiments have reported clouds absorbing more solar radiation than theory could predict. In the visible spectrum, simulations based on optical constants of water lead to negligible cloud absorption. This result had been explored by some experimentalists to calibrate the cloud absorption measurements. However, the author and his collaborators recently discovered that visible light can directly cleave off water molecular clusters at liquid-air interfaces (PNAS, e2312751120, 2023; e2320844121, 2024), which is named the photomolecular effect in analogy to the photoelectric effect. This discovery suggests that a crucial piece of physics has been missing in the existing theories: light can be absorbed at water-air interface. The photomolecular effect can be simulated by generalizing the boundary conditions for the Maxwell equations using Feibelman parameters that were derived in the past research on the surface photoelectric effect and surface plasmons. In this work, the author uses simulation to show that including the photomolecular effect at the air-water interface can potentially explain the cloud absorption anomaly. Although the lack of accurate Feibelman parameter values prevents a direct comparison of the current theory with experiments, this work points to an unexplored mechanism for explaining the cloud absorption anomaly and calls for further investigation on the impacts of photomolecular effect in the climate modeling.
title Photomolecular Effect as A Potential Explanation for The Cloud Absorption Anomaly
topic Atmospheric and Oceanic Physics
Applied Physics
Optics
url https://arxiv.org/abs/2502.15121