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石墨烯层间显著的弹道热输运:纳米孔和锂插层的影响
Significant ballistic thermal transport across graphene layers: Effect of nanoholes and lithium intercalation
| 作者 | John Crosby · Haoran Cui · Yan Wang |
| 期刊 | Applied Physics Letters |
| 出版日期 | 2025年1月 |
| 卷/期 | 第 127 卷 第 8 期 |
| 技术分类 | 储能系统技术 |
| 技术标签 | 储能系统 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | 多孔石墨烯 石墨 面外热输运 纳米孔 锂离子插层 |
语言:
中文摘要
多孔石墨烯和石墨因其独特的结构与热学特性,在电化学储能和光热应用中日益受到关注。本研究系统分析了含孔石墨及多层石墨烯的晶格热输运行为与声子谱特征。结果表明,相对于石墨烯基面呈倾斜传播的声子模式是跨平面热输运的主要贡献者,且表现出显著的弹道特性,导致跨平面热导率随层数近似线性增加。石墨烯中引入纳米孔会宽频抑制跨平面声子输运,而锂离子插层则有望增强该输运。研究揭示了关键石墨烯结构中跨平面热传导的内在机制,为热管理材料设计提供了重要指导。
English Abstract
Porous graphene and graphite are increasingly utilized in electrochemical energy storage and solar-thermal applications due to their unique structural and thermal properties. In this study, we conduct a comprehensive analysis of the lattice thermal transport and spectral phonon characteristics of holey graphite and multilayer graphene. Our results reveal that phonon modes propagating obliquely with respect to the graphene basal planes are the primary contributors to cross-plane thermal transport. These modes exhibit a predominantly ballistic nature, resulting in an almost linear increase in cross-plane thermal conductivity with the number of layers. The presence of nanoholes in graphene induces a broadband suppression of cross-plane phonon transport, whereas lithium-ion intercalation shows potential to enhance it. These findings provide critical insights into the mechanisms governing cross-plane heat conduction in key graphene-based structures, offering valuable guidance for thermal ma
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SunView 深度解读
该石墨烯跨平面热输运研究对阳光电源储能系统热管理具有重要价值。研究揭示的纳米孔抑制热传导和锂插层增强热输运机制,可直接应用于PowerTitan大型储能系统和ST系列储能变流器的热界面材料优化。通过调控石墨烯层间结构,可实现电池模组与功率器件的定向导热设计:在需要隔热的区域引入多孔石墨烯降低热桥效应,在散热通道采用锂改性石墨烯提升跨层导热率。该技术对SiC/GaN功率模块的散热优化尤为关键,可提升储能变流器功率密度,并为电动汽车电池包热管理提供新型轻量化导热材料方案,增强系统安全性与循环寿命。