Titanium dioxide/graphene oxide synergetic reinforced composite phase change materials with excellent thermal energy storage and photo-thermal performances

Tingfeng Xia, Bojing Wu, Huanzhi Zhang, Fen Xu, Lixian Sun, Xiangcheng Lin, Caihang Liang, Lei Ma, Hongliang Peng, Bin Li, Erhu Yan
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Abstract

The development of advanced composite solid-solid phase change materials (SSPCMs) is urgent to explore for improving solar energy harvesting and storage. Herein, novel composite SSPCMs with synergetic cross-linking structure were fabricated through polymerization using GO and TiO constructed on the polyurethane framework skeleton. GO and TiO synergetic enhanced polymer framework played a role as skeletal structure to encapsulate PEG in the molecular chains, and provided as highly thermal conductive pathways for the composite SSPCMs. TiO nanoparticles performed as extended surface on the skeletal structure for further improvement in thermal conductivity. The composite SSPCMs exhibited a remarkably improved thermal conductivity as high as 0.7 W/(m‧K) and fast thermal response rate. The good light adsorption property of TiO enhanced the light absorbance efficiency of the composite SSPCMs by 94.4%. And the photo-thermal conversion efficiency of the composite SSPCMs highly reached 93.5%. Meanwhile, the composite SSPCMs exhibited excellent anti-leakage performance and shape stability under high temperature. Consequently, the as-prepared composite SSPCMs possessed a potential for applications in thermal energy storage and solar energy utilization systems.
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具有优异热能储存和光热性能的二氧化钛/氧化石墨烯协同增强复合相变材料
开发先进的复合固固相变材料(SSPCMs)是改善太阳能收集和储存的迫切探索。本文利用聚氨酯骨架上构建的 GO 和 TiO,通过聚合作用制备了具有协同交联结构的新型复合固固相变材料。GO和TiO协同增强聚合物骨架起到了骨架结构的作用,将PEG包裹在分子链中,并为复合SSPCM提供了高导热通道。TiO 纳米粒子作为骨架结构的扩展表面,进一步提高了导热性。复合 SSPCMs 的热导率显著提高,高达 0.7 W/(m‧K),热响应速度快。TiO 的良好光吸附特性使复合 SSPCM 的光吸收率提高了 94.4%。复合 SSPCMs 的光热转换效率高达 93.5%。同时,复合 SSPCMs 在高温下具有优异的抗渗漏性能和形状稳定性。因此,制备的复合 SSPCMs 具有在热能储存和太阳能利用系统中应用的潜力。
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