Temperature and isotope effects on the thermoelectric properties in SnTe

Yong Lu; Fawei Zheng; Ping Zhang; Xiaohong Shao; Dong Bo Zhang

doi:10.1088/1361-648X/aa63a9

Temperature and isotope effects on the thermoelectric properties in SnTe

Yong Lu, Fawei Zheng, Ping Zhang, Xiaohong Shao, Dong Bo Zhang

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

The temperature and Sn isotope effects on SnTe are investigated using the hybrid scheme that combines ab initio molecular dynamics and lattice dynamics (AIMD + LD). The unstable softening of TA phonon mode at 0 K in cubic phase SnTe disappears and the TO mode is stiffened by considering the temperature effect, in agreement with the inelastic neutron scattering (INS) observations. A linear dependence on isotope mass of phonon frequency, lifetime, and mean free path for isolate phonon mode is observed with the possibility of positive, negative, and nearly zero shifts. The lattice thermal conductivity () shows saturation characteristic as Sn isotope mass increases to ¹²⁰SnTe, with an increase rate of ∼2.1% from ¹¹²SnTe to ¹²⁴SnTe. Considering the effects of partial isotope doping, we obtain a reduced with respect to the undoped case. The is reduced by ∼14.6% at 600 K when considering the volumetric expansion.

Original language	English
Article number	175701
Journal	Journal of Physics Condensed Matter
Volume	29
Issue number	17
DOIs	https://doi.org/10.1088/1361-648X/aa63a9
Publication status	Published - 23 Mar 2017
Externally published	Yes

Keywords

isotope effect
phonon quasi-particle
thermoelectric property

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10.1088/1361-648X/aa63a9

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title = "Temperature and isotope effects on the thermoelectric properties in SnTe",

abstract = "The temperature and Sn isotope effects on SnTe are investigated using the hybrid scheme that combines ab initio molecular dynamics and lattice dynamics (AIMD + LD). The unstable softening of TA phonon mode at 0 K in cubic phase SnTe disappears and the TO mode is stiffened by considering the temperature effect, in agreement with the inelastic neutron scattering (INS) observations. A linear dependence on isotope mass of phonon frequency, lifetime, and mean free path for isolate phonon mode is observed with the possibility of positive, negative, and nearly zero shifts. The lattice thermal conductivity () shows saturation characteristic as Sn isotope mass increases to 120SnTe, with an increase rate of ∼2.1% from 112SnTe to 124SnTe. Considering the effects of partial isotope doping, we obtain a reduced with respect to the undoped case. The is reduced by ∼14.6% at 600 K when considering the volumetric expansion.",

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T1 - Temperature and isotope effects on the thermoelectric properties in SnTe

AU - Lu, Yong

AU - Zheng, Fawei

AU - Zhang, Ping

AU - Shao, Xiaohong

AU - Zhang, Dong Bo

PY - 2017/3/23

Y1 - 2017/3/23

N2 - The temperature and Sn isotope effects on SnTe are investigated using the hybrid scheme that combines ab initio molecular dynamics and lattice dynamics (AIMD + LD). The unstable softening of TA phonon mode at 0 K in cubic phase SnTe disappears and the TO mode is stiffened by considering the temperature effect, in agreement with the inelastic neutron scattering (INS) observations. A linear dependence on isotope mass of phonon frequency, lifetime, and mean free path for isolate phonon mode is observed with the possibility of positive, negative, and nearly zero shifts. The lattice thermal conductivity () shows saturation characteristic as Sn isotope mass increases to 120SnTe, with an increase rate of ∼2.1% from 112SnTe to 124SnTe. Considering the effects of partial isotope doping, we obtain a reduced with respect to the undoped case. The is reduced by ∼14.6% at 600 K when considering the volumetric expansion.

AB - The temperature and Sn isotope effects on SnTe are investigated using the hybrid scheme that combines ab initio molecular dynamics and lattice dynamics (AIMD + LD). The unstable softening of TA phonon mode at 0 K in cubic phase SnTe disappears and the TO mode is stiffened by considering the temperature effect, in agreement with the inelastic neutron scattering (INS) observations. A linear dependence on isotope mass of phonon frequency, lifetime, and mean free path for isolate phonon mode is observed with the possibility of positive, negative, and nearly zero shifts. The lattice thermal conductivity () shows saturation characteristic as Sn isotope mass increases to 120SnTe, with an increase rate of ∼2.1% from 112SnTe to 124SnTe. Considering the effects of partial isotope doping, we obtain a reduced with respect to the undoped case. The is reduced by ∼14.6% at 600 K when considering the volumetric expansion.

KW - isotope effect

KW - phonon quasi-particle

KW - thermoelectric property

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Temperature and isotope effects on the thermoelectric properties in SnTe

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