材料科学
散热片
数码产品
小型化
电子设备和系统的热管理
纳米技术
热导率
光电子学
石墨烯
发射率
热的
传热
纳米片
选择性表面
辐射冷却
晶体管
铜
焊接
发热
电力电子
消散
柔性电子器件
化学气相沉积
功率密度
工作(物理)
焦耳加热
红外线的
被动冷却
热辐射
热撒布器
作者
Qiang Zhao,Ying Wang,Xiang Zheng,Xiaolu Cai,Jingze Li,Yongqi Zhang,Xinhui Xia
出处
期刊:Nanoscale
[Royal Society of Chemistry]
日期:2025-12-10
卷期号:18 (3): 1607-1618
摘要
The relentless pursuit of higher power density and miniaturization of modern electronics demand have exposed the limitations of conventional passive cooling systems. This study presents an innovative quasi-honeycomb architecture composed of vertically aligned and interconnected graphene nanosheet arrays (VIG) synthesized via plasma-enhanced chemical vapor deposition (PECVD) on copper substrates, achieving dual-mode heat dissipation through synergistic radiative and convective enhancement. The engineered graphene-copper hybrid interface demonstrates exceptional thermal performance, achieving an enhanced heat transfer coefficient of 35.6 W m-2 K-1 through synergistic optimization of infrared emissivity and specific surface area. Systematic evaluations reveal a 21.6% improvement in cooling efficiency compared to pristine copper substrates. Practical implementation as a conformal passive heat sink effectively suppresses temperature rise in high-power LED arrays (ΔT reduction: 28.1 °C at 2.7 W) and lithium-ion battery modules (thermal mitigation: 7.0 °C under 3C discharge). Notably, the ultrathin (≈2.5 μm) and ultralight (≈0.073 mg cm-2) structure enables spontaneous self-assembly on sub-100 μm metallic foils, providing geometrically adaptive heat dissipation for irregular surfaces. This work establishes a universal paradigm for developing conformal thermal management solutions compatible with geometrically complex surfaces in next-generation compact electronics.
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