Superconductivity in efficient thermoelectric Cu$_3$Sb$_{0.98}$Al$_{0.02}$Se$_4$

Alexander G. Gavriliuk; Di Li; Ho-kwang Mao; Qiao-Wei Huang; Viktor V. Struzhkin; Xiao-Jia Chen; Xiao-Miao Zhao; Xiao-Ying Qin; Xi-Yu Li; Yong-Hui Zhou

arxiv: 1501.03382 · v1 · pith:EJTJNMDLnew · submitted 2015-01-13 · ❄️ cond-mat.supr-con · cond-mat.mtrl-sci

Superconductivity in efficient thermoelectric Cu₃Sb_(0.98)Al_(0.02)Se₄

Xiao-Miao Zhao , Yong-Hui Zhou , Qiao-Wei Huang , Viktor V. Struzhkin , Ho-kwang Mao , Alexander G. Gavriliuk , Xiao-Ying Qin , Di Li

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Xi-Yu Li Yuan-Yue Li Xiao-Jia Chen

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classification ❄️ cond-mat.supr-con cond-mat.mtrl-sci

keywords thermoelectricsuperconductivityefficientphasepressureachieveadvancementsalloy

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Both superconductivity and thermoelectricity offer promising prospects for daily energy efficiency applications. The advancements of thermoelectric materials have led to the huge improvement of the thermoelectric figure of merit in the past decade. By applying pressure on a highly efficient thermoelectric material Cu$_{3}$Sb$_{0.98}$Al$_{0.02}$Se$_4$, we achieve dome-shape superconductivity developing at around 8.5 GPa but having a maximum critical temperature of 3.2 K at pressure of 12.7 GPa. The novel superconductor is realized through the first-order structural transformation from its initial phase to an orthorhombic one. The superconducting phase is determined in the ultimate formation of the Cu-Al-Sb-Se alloy.

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Superconductivity in efficient thermoelectric Cu₃Sb_(0.98)Al_(0.02)Se₄

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