材料科学
能量转换效率
复合数
纳米技术
光热治疗
磷烯
热的
能量转换
复合材料
热导率
热能
环境友好型
热效率
纳米复合材料
太阳能
光电子学
纳米颗粒
等温过程
高效能源利用
余热
热稳定性
热阻
各向异性
纳米尺度
工作(物理)
作者
Yang Meng,Feng Wu,Yuchan Li,Zhe Xiang,Mengyuan Luo,Xinxin Sheng,Delong Xie
摘要
ABSTRACT Efficient and durable solar thermal utilization requires composite phase change materials (CPCMs) that integrate high photothermal efficiency, stable energy storage, and environmental robustness within a scalable architecture. However, most CPCMs rely on energy‐intensive processing or carbon‐based frameworks, hindering the simultaneous realization of multifunctionality and sustainability. Herein, a series of carbonization‐free, interface‐engineered bio‐based CPCMs are developed by functionalizing the anisotropic microchannel structure of delignified balsa wood with black phosphorene and metal‐polyphenol network (tannin‐Fe 3+ ). The hybrid interface is further in situ reduced Ag nanoparticles and post‐grafted octadecyl chains, creating a robust superhydrophobic surface. Interfacial regulation improves wood‐based CPCMs compatibility and stability, delivering a latent heat of ∼175.03 kJ kg −1 with suppressed supercooling. Leveraging directional heat pathways, photothermal–plasmonic coupling, and broadband absorption, the CPCMs achieve a photothermal conversion efficiency of 91.27% and a ∼3.9‐fold increase in axial thermal conductivity. The as‐prepared CPCMs further integrates flame retardancy, superhydrophobicity, and antimicrobial activity, thereby mitigating dust adhesion and microbial colonization that would otherwise deteriorate the outdoor photothermal performance. As a proof of concept, stable solar–thermal–electric conversion is demonstrated with an output voltage of up to 0.65 V under one‐sun irradiation. This work presents a scalable and environmentally friendly wood‐based platform for advanced solar thermal energy harvesting.
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