The thermal conductivity measurement of metal−organic frameworks (MOFs), which plays an important role in thermal management of MOF-based gas separation, storage, and thermal energy conversion (e.g., adsorption heat pumps), has been a challenging task for decades. However, the direct thermal conductivity measurement of a single-crystal MOF is currently limited by their small crystal sizes, since no sophisticated approach has ever been reported. In this study, the Raman-resistance temperature detectors (Raman-RTDs) method was developed for in situ measuring of the thermal conductivity of single-crystal ZIF-8, whose system error resulting from the thermal contact resistance between sample and RTDs can be eliminated. According to the dependence of thermal resistance of MOF crystals on the laser spot location, the thermal conductivities of polycrystalline and single-crystal ZIF-8 were derived to be 0.21 ± 0.03 and 0.64 ± 0.09 W/(m•K), respectively. The proposed in situ thermal conductivity measurement method may be further extended to other types of microscale particles.
Advanced heat‐managing textiles not only improve the comfort of individual but also reduce the energy consumption of the heat‐managing systems of building. To meet the demand of heat‐managing in a dynamic environment, responsive textiles with tunable thermal convection and radiation have been developed, while the design of fabrics with tunable thermal conduction remains unexplored. Here, a humidity‐driven and flexible thermal conductance regulating material is developed that shows an unprecedented switching ratio up to 14×, which is composed of brick‐and‐mortar structured graphene and silk sericin (GS). This work investigates the microstructure variation in response to humidity experimentally and theoretically. The regulation can be ascribed to the hydration/dehydration of sericin and the subsequent changing in graphene–sericin interfacial thermal conductance. It is demonstrated that the GS can be facilely coated on ordinary textiles through dyeing to achieve responsive thermal‐managing clothes with a significant and reversible response toward the variation of environment humidity.
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