Smart thermal management of bio-based aerogels: A paradigm shift from energy localisation to zero-energy anti-icing
バイオベースエアロゲルのスマート熱管理:エネルギー局在化からゼロエネルギー防氷へのパラダイムシフト (AI 翻訳)
Jincheng Su, Jiliang Wang, Wei Zhou, Xiaozhuang Yang, Qinghua Miao, Bing Wang
🤖 gxceed AI 要約
日本語
本レビューは、バイオベースエアロゲルを用いた太陽熱駆動のゼロエネルギー防氷技術を体系的に紹介。局在化から能動的熱管理へのパラダイムシフトを提案し、マルチスケール設計により太陽光1照射下で60°C以上の昇温と0.025 W/(m·K)以下の熱伝導率を達成する可能性を示す。動的エネルギー整合や環境耐久性などの課題も指摘。
English
This review systematically explores bio-based aerogels for solar-powered zero-energy anti-icing, proposing a paradigm shift from passive insulation to active thermal management. It highlights cross-scale design strategies achieving >60°C surface temperature rise under 1 sun and thermal conductivity <0.025 W/(m·K), while identifying research gaps in dynamic energy matching and environmental durability.
Unofficial AI-generated summary based on the public title and abstract. Not an official translation.
📝 gxceed 編集解説 — Why this matters
日本のGX文脈において
本論文は直接的なGX政策(SSBJ/TCFD等)には関与しないが、省エネ防氷技術として日本の寒冷地インフラのエネルギー消費削減に寄与する可能性がある。再生可能エネルギー活用の観点から、GX技術ポートフォリオの一部として注目できる。
In the global GX context
While not directly about climate disclosure or carbon accounting, this review contributes to the global energy transition by proposing solar-powered zero-energy anti-icing materials, potentially reducing electricity demand for de-icing in cold regions.
👥 読者別の含意
🔬研究者:Materials scientists working on sustainable anti-icing solutions will find a comprehensive overview of bio-based aerogel design and performance.
📄 Abstract(原文)
Given the global energy crises and severe climate challenges, it is urgent to develop zero-energy anti-icing technologies to ensure infrastructure security. Bio-based aerogels, due to their environmental friendliness and renewable characteristics, excellent thermal insulation properties and structural design flexibility, provide an innovative opportunity for solar-pow-ered intelligent thermal management. Therefore, we systematically review recent developments in bio-based aerogels for intelligent thermal management. The concept of ‘localisation of solar thermal energy’ is proposed to highlight a paradigm shift from passive insulation to active thermal management platforms. Through a critical analysis of green interface cou-pling, biomimetic anisotropic structures and photothermal-phase transition sequences, the importance of rational cross-scale design in overcoming performance barriers (such as high porosity, high strength, low thermal conductivity and high photothermal efficiency) is emphasised. In addition, research gaps in dynamic energy matching, environmental durability and system integration are identified, providing a theoretical framework and development path for designing future intel-ligent anti-icing materials. This review demonstrates that through integrated multi-scale design, bio-based aerogels can achieve a surface temperature increase of over 60°C under 1 solar irradiance, and maintain the bulk thermal conductivity below 0.025 W/(m K). This finding indicates a promising approach to achieving zero-energy anti-icing solutions.
🔗 Provenance — このレコードを発見したソース
- openalex https://doi.org/10.24425/ather.2026.158672first seen 2026-05-15 17:16:36 · last seen 2026-06-07 05:02:08
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