Origin of the weakly temperature-dependent thermal conductivity in ZIF-4 and ZIF-62
YG Zhou and YX Xu and YF Gao and S Volz, PHYSICAL REVIEW MATERIALS, 6, 015403 (2022).
DOI: 10.1103/PhysRevMaterials.6.015403
It is known that the temperature-dependent thermal conductivity of conventional crystals follows the classical 1/T trend due to the dominant umklapp phonon-phonon scattering at high enough temperatures. However, the thermal conductivity of many crystalline metal-organic frameworks is very low and shows a weak temperature dependence when all the vibrational modes are occupied. By studying two metal-organic frameworks, i.e., zeolitic imidazolate framework-4 (ZIF-4) and crystal zeolitic imidazolate framework-62 (ZIF-62), we computationally prove that the ultralow thermal conductivity in ZIF-4 and ZIF-62 is resulting from the strong scattering among the vibrations due to the large mass difference between the metal atom and the organic sites and the large diffusion of organic sites. Unlike only propagating vibrational modes, i.e., phonons, existing in the conventional crystalline Si, our mean free path spectrum analysis uncovers that both propagating and nonpropagating anharmonic vibrational modes exist and contribute largely to thermal conductivity in ZIF-4 and ZIF-62. The obtained weak temperature dependence of thermal conductivity is found to stem from the temperature dependencies of those two kinds of vibrations. Our study provides a fundamental understanding of thermal transport in metal- organic frameworks and will guide the design of thermal-related applications, e.g., inflammable gas storage, chemical catalysis, and solar thermal conversion.
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