Ye Zefang, Park Janghan, Zhou Yongjian, Montano Raul D, Pandey Tribhuwan, Zhang Yanyao, Lin Jung-Fu, Wang Yaguo
Walker Department of Mechanical Engineering, <a href="https://ror.org/00hj54h04">The University of Texas at Austin</a>, Austin, Texas 78712, USA.
Department of Physics, <a href="https://ror.org/008x57b05">University of Antwerp</a>, Groenenborgerlaan 171, Antwerp B-2020, Belgium.
Phys Rev Lett. 2024 Nov 15;133(20):206301. doi: 10.1103/PhysRevLett.133.206301.
Carbon materials display intriguing physical properties, including superconductivity and highly anisotropic thermal conductivity found in graphene. Compressive strain can induce structural and bonding transitions in carbon materials and create new carbon phases, but their interplay with thermal conductivity remains largely unexplored. We investigated the in situ high-pressure thermal conductivity of compressed graphitic phases using picosecond transient thermoreflectance and first-principles calculations. Our results show an anomalous thermal conductivity that peaks to 260 W/mK at 15-20 GPa but drops to 3.0 W/mK at ∼35 GPa. Together with complimentary in situ Raman and x-ray diffraction results, the abnormal thermal conductivity trend of compressed carbon is attributed to phonon-mediated conductivity influenced by interlayer buckling and sp^{2} to sp^{3} transition and, subsequently, the formation of M-carbon nanocrystals and amorphous carbon. Strain-induced structural and bonding variations provide a wide-range manipulation of thermal and mechanical properties in carbon materials.
碳材料具有引人入胜的物理性质,包括石墨烯中发现的超导性和高度各向异性的热导率。压缩应变可在碳材料中诱导结构和键合转变,并产生新的碳相,但其与热导率之间的相互作用在很大程度上仍未得到探索。我们使用皮秒瞬态热反射和第一性原理计算研究了压缩石墨相的原位高压热导率。我们的结果显示出异常的热导率,在15 - 20吉帕时峰值达到260瓦/米·开尔文,但在约35吉帕时降至3.0瓦/米·开尔文。结合原位拉曼和X射线衍射的补充结果,压缩碳的异常热导率趋势归因于受层间屈曲和sp²到sp³转变影响的声子介导的导电性,以及随后M - 碳纳米晶体和非晶碳的形成。应变诱导的结构和键合变化为碳材料的热学和力学性能提供了广泛的调控。
