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Unusual electronic and vibrational properties in the colossal thermopower material FeSb₂

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arxiv 1808.04786 v1 pith:QZVZYQJR submitted 2018-08-14 cond-mat.str-el

Unusual electronic and vibrational properties in the colossal thermopower material FeSb₂

classification cond-mat.str-el
keywords temperaturebehaviorelectronicmaterialopticalpropertiesalongaxis
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The iron antimonide FeSb$_2$ possesses an extraordinarily high thermoelectric power factor at low temperature, making it a leading candidate for cryogenic thermoelectric cooling devices. However, the origin of this unusual behavior is controversial, having been variously attributed to electronic correlations as well as the phonon-drag effect. The optical properties of a material provide information on both the electronic and vibrational properties. The optical conductivity reveals an anisotropic response at room temperature; the low-frequency optical conductivity decreases rapidly with temperature, signalling a metal-insulator transition. One-dimensional semiconducting behavior is observed along the $b$ axis at low temperature, in agreement with first-principle calculations. The infrared-active lattice vibrations are also symmetric and extremely narrow, indicating long phonon relaxation times and a lack of electron-phonon coupling. Surprisingly, there are more lattice modes along the $a$ axis than are predicted from group theory; several of these modes undergo significant changes below about 100 K, hinting at a weak structural distortion or phase transition. While the extremely narrow phonon line shapes favor the phonon-drag effect, the one-dimensional behavior of this system at low temperature may also contribute to the extraordinarily high thermopower observed in this material.

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