Development and application progress of chitosan-based phase change materials- A review
キトサンベースの相変化材料の開発と応用の進展:レビュー (AI 翻訳)
Zhang Yi, Da Hairong
🤖 gxceed AI 要約
日本語
本レビューは、キトサンをベースとした相変化材料(PCM)の調製戦略と応用を体系的にまとめた。物理混合、グラフト改質、マイクロカプセル化、担体吸着の4つの主要手法を比較し、ドラッグデリバリー、建築エネルギー効率、電子機器の熱管理など多様な応用分野を示した。将来の課題として、熱伝導率の向上とサイクル安定性の改善を挙げている。
English
This review systematically covers preparation strategies and applications of chitosan-based phase change materials (PCMs). It compares four main routes: physical blending, graft modification, microencapsulation, and carrier adsorption, and demonstrates applications in drug delivery, building energy efficiency, and thermal management of electronics. Future challenges include improving thermal conductivity and cycling stability.
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
日本のGX文脈では、建築のエネルギー効率向上や再生可能エネルギー熱利用に貢献する可能性がある材料技術として注目される。ただし、具体的な日本政策や規制との連動は直接的ではない。
In the global GX context
This review contributes to global energy storage materials research, supporting thermal management in buildings and electronics, which aligns with energy efficiency goals under global decarbonization efforts. It does not address disclosure or policy but provides material solutions for energy transition.
👥 読者別の含意
🔬研究者:このレビューは、キトサンベースの相変化材料の総合的な知見を提供し、エネルギー貯蔵材料の研究者にとって有益である。
📄 Abstract(原文)
Driven by the "dual carbon" strategic goals, phase change materials (PCMs) have become a research frontier in the energy sector, thanks to their superior latent heat storage and release capabilities during reversible phase transition processes. Biobased polymers offer an effective solution to mitigate the environmental burdens imposed by traditional petroleum-based PCMs. Chitosan, featuring prominent advantages such as non-toxicity, biodegradability, abundant reactive sites, and ease of modification, serves as an ideal matrix for constructing high-performance composite PCMs. This paper systematically reviews the research advances in the preparation strategies and applications of chitosan-based PCMs. The core contribution of this review lies in its exclusive focus on chitosan as a bio-based matrix/shell, quantitative comparison of four typical preparation routes, and critical analysis of performance–structure–application relationships. The preparation strategies mainly encompass physical blending, graft modification, microencapsulation, and carrier adsorption, each with distinct characteristics. Relevant studies have validated their feasibility and performance merits. The application scope of such materials has been extended to drug delivery, tissue engineering, intelligent thermoregulatory textiles, food preservation and packaging, building energy efficiency, and thermal management of electronic devices, exhibiting broad application prospects. Looking ahead, efforts should be focused on addressing current bottlenecks including low thermal conductivity, insufficient cycling stability, and poor scalability, and developing multifunctional intelligent materials with high energy storage density, rapid responsiveness, long cycle life, and low environmental footprint. Through interdisciplinary collaborative innovation, the breakthrough application of chitosan-based PCMs in more high-value fields will be promoted.
🔗 Provenance — このレコードを発見したソース
- openalex https://doi.org/10.1016/j.cartre.2026.100649first seen 2026-05-17 07:10:41 · last seen 2026-05-20 05:16:08
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