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تسجيل مستخدم جديدA Generic Microscopic Theory for the Universality of TTLS Model Meissner-Berret Ratio in Low-Temperature Glasses
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Tunneling-two-level-system (TTLS) model has successfully explained several low-temperature glass universal properties which do not exist in their crystalline counterparts. The coupling constants between longitudinal and transverse phonon strain fields and two-level-systems are denoted as $gamma_l$ and $gamma_t$. The ratio $gamma_l/gamma_t$ was observed to lie between $1.44$ and $1.84$ for 18 different kinds of glasses. Such universal property cannot be explained within TTLS model. In this paper by developing a microscopic generic coupled block model, we show that the ratio $gamma_l/gamma_t$ is proportinal to the ratio of sound velocity $c_l/c_t$. We prove that the universality of $gamma_l/gamma_t$ essentially comes from the mutual interaction between different glass blocks, independent of the microscopic structure and chemical compound of the amorphous materials. In the appendix we also give a detailed correction on the coefficient of non-elastic stress-stress interaction $Lambda_{ijkl}^{(ss)}$ which was obtained by Joffrin and Levelutcite{Joffrin1976}.
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