Thermal conductivity of graphene coated copper under uniaxial tensile mechanical strain.

IF 4.6 3区材料科学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Nanoscale Advances Pub Date : 2025-05-08 DOI:10.1039/d5na00088b

Micah P Vallin, Hisato Yamaguchi, Rijan Karkee, Chanho Lee, Ramon M Martinez, Saryu J Fensin, Jun Beom Park, Hi Tin Vo, Richard Z Zhang, Michael T Pettes

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Abstract

Graphene continues to demonstrate promise as a highly effective barrier coating, even at only one atom thick. The thermal properties of this coating are also promising to allow diffusion of heat across the surface, as the isolated graphene is an intrinsically good thermal conductor. However, this and its behavior under mechanical deformation have been less extensively studied. This report demonstrates that the in-plane thermal conductivity and interfacial thermal conductance of graphene coatings on copper are affected by mechanical strain. By inducing strain in the copper substrate, the Raman-active 2D peak exhibits a change in position and a change in laser power dependence as the copper substrate is uniaxially elongated to a maximum of 0.5%. Non-linear trends in thermal conductivity are observed with tensile strain in samples with differing strain transfer rates from the substrate, indicating the close correlation between intrinsic thermal conduction and interfacial properties in atomically thin coatings transferred onto metals.

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石墨烯包覆铜在单轴拉伸机械应变下的导热性能。

即使石墨烯只有一个原子厚，它仍有望成为一种高效的屏障涂层。这种涂层的热性能也有望允许热量在表面扩散，因为隔离的石墨烯本质上是一种良好的热导体。然而，对这种材料及其在机械变形下的行为研究较少。本文证明了石墨烯涂层的面内导热系数和界面导热系数受到机械应变的影响。通过在铜衬底中诱导应变，当铜衬底单轴伸长至最大0.5%时，拉曼活性二维峰的位置发生了变化，激光功率依赖性也发生了变化。在基底应变传递速率不同的样品中，观察到热导率随拉伸应变的非线性趋势，表明在转移到金属上的原子薄涂层中，本征热传导与界面性能密切相关。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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