ABSTRACT Radiative cooling (RC) offers a transformative, zero‐energy pathway for thermal management, yet conventional materials are often stymied by intricate fabrication, high costs, and environmental toxicity. Lignocellulose‐mediated radiative cooling materials (L‐MRCMs) have emerged as a sustainable solution, but the field currently lacks a unified framework to navigate the trade‐offs between their multi‐scale hierarchical structures and the precise optical demands of the atmospheric window. This review addresses this gap by systematically elucidating the fundamental physics of RC through the lens of lignocellulosic engineering. The physicochemical challenges of transforming lignocellulose into high‐performance emitters, focusing on the synergetic coordination of solar reflectance and mid‐infrared emittance, were analyzed and summarized in depth. Furthermore, this work summarizes core design principles and performance benchmarks across diverse sectors, including energy‐efficient architecture, moisture harvesting, and personal thermal management. The main challenges hindering the development of L‐MRCMs are also outlined, along with potential strategies to overcome them, aiming to promote their commercialization and broader application in green technologies.
Liu et al. (Wed,) studied this question.