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What is the thermal conductivity of Li6PS5I?

Relaxation (NMR)

Ionic conductivity

Solid-state battery

Lithium battery

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The thermal conductivity of Li6PS5I is not mentioned in any of the provided abstracts.

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Journal Article•DOI Silicon-Doped Argyrodite Solid Electrolyte Li6PS5I with Improved Ionic Conductivity and Interfacial Compatibility for High-Performance All-Solid-State Lithium Batteries. Jun Zhang, Lujie Li, Chao Zheng, Yang Xia, Yongping Gan, Hui Huang, Chu Liang, He Xinping, Xinyong Tao, Zhang Wenkui - Show less +9 more 21 Aug 2020-ACS Applied Materials & Interfaces 79 Citations	The paper does not provide information about the thermal conductivity of Li6PS5I.
Journal Article•DOI Achieving superior ionic conductivity of Li6PS5I via introducing LiCl Cong Liao, Chuang Yu, Linfeng Peng, Xuefei Miao, Shuai Chen, Ziqi Zhang, Shijie Cheng, Jia Xie - Show less +7 more 01 Apr 2022-Solid State Ionics 10 Citations	The provided paper does not mention the thermal conductivity of Li6PS5I.
Open access•Journal Article•DOI With a Little Help from 31P NMR: The Complete Picture on Localized and Long-Range Li+ Diffusion in Li6PS5I. Katharina Hogrefe, Isabel Hanghofer, H. Martin R. Wilkening - Show less +2 more 11 Oct 2021-Journal of Physical Chemistry C 6 Citations	The provided paper does not mention the thermal conductivity of Li6PS5I.
Journal Article•DOI Synthetic optimization and application of Li-argyrodite Li6PS5I in solid-state battery at different temperatures Zhen-Yuan He, Ziqi Zhang, Ming Yu, Chuang Yu, Hao-Tian Ren, Jun-Zhao Zhang, Linfeng Peng, Long Zhang, Shijie Cheng, Jia Xie - Show less +9 more 15 Sep 2021-Rare Metals 13 Citations	The provided paper does not mention the thermal conductivity of Li6PS5I.
Journal Article•DOI Failure analysis of the Ge-substituted Li6PS5I with bare LiNi0.8Co0.1Mn0.1O2 and performance improvement via Li2ZrO3 coating Ziqi Zhang, Jing Yao, Chuang Yu, Ruonan Xu, Jun-ping Ma, Chaochao Wei, Linfeng Peng, Long Zhang, Shijie Cheng, Jia Xie - Show less +9 more 01 Jan 2022-Journal of materials chemistry. A, Materials for energy and sustainability	The provided paper does not mention the thermal conductivity of Li6PS5I.

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What is the thermal conductivity of an insulation material?5 answersThe thermal conductivity of an insulation material refers to its ability to conduct heat. It is an important parameter in determining the energy efficiency of buildings and other industries that use insulation materials. The thermal conductivity of insulation materials can be influenced by factors such as temperature, moisture content, density, and the type of material used. Studies have shown that the thermal conductivity of insulation materials can increase with increasing temperature and humidity, but the degree of change varies depending on the specific material. Moisture transfer in the building envelope can also have a significant impact on the heat transfer process. Experimental methods, such as the guarded hot plate method, are commonly used to measure the thermal conductivity of insulation materials.

What is the thermal conductivity of NaI?4 answersThe thermal conductivity of NaI has been studied in several papers. The Leibfried-Schlomann formula is found to be a better description for NaCl than for NaI. The effect of optic phonons on thermal conductivity cannot be ignored for both NaCl and NaI, but taking only acoustic phonons into account is a better approximation for NaI due to the larger ionic mass ratio. Unfortunately, no specific value for the thermal conductivity of NaI is mentioned in the abstracts provided.

What is the thermal conductivity of NaF?5 answersThe thermal conductivity of NaF is not explicitly mentioned in the abstracts provided.

How to find thermal conductivity of a material?5 answersThermal conductivity of a material can be determined using various methods. One approach is to measure the thermal conductivity by applying Newton's law of cooling to specimens in the form of a disc. Another method involves using the bolometric effect, where laser beam heating creates a temperature gradient over the nanomaterial, and the resulting change in electrical resistance is used to extract the temperature profile and determine thermal conductivity. Additionally, the ohmic pulse-heating method can be used to investigate thermal conductivity and thermal diffusivity of metals and alloys, particularly in the solid and liquid phases. These methods provide valuable insights into the thermal conductivity of different materials and can be used to characterize their properties.

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