Two-dimensional InSe as a potential thermoelectric material

Two-dimensional InSe as a potential thermoelectric material

Thermoelectric properties of monolayer indium selenide (InSe) are investigated by using Boltzmann transport theory and first-principles calculations as a function of Fermi energy and crystal orientation. We find that the maximum power factor of p-type (n-type) monolayer InSe can be as large as 0.049...

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Veröffentlicht in:Applied physics letters 2017-08, Vol.111 (9)
Hauptverfasser: Hung, Nguyen T., Nugraha, Ahmad R. T., Saito, Riichiro
Format: Artikel
Sprache:eng
Schlagworte:
Applied physics
Conduction bands
Crystal structure
Density of states
Electrical resistivity
First principles
Indium selenides
Mathematical analysis
Maximum power
Monolayers
Power factor
Quantum theory
Seebeck effect
Thermoelectric materials
Thermoelectricity
Transport theory
Valence band
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Zusammenfassung:Thermoelectric properties of monolayer indium selenide (InSe) are investigated by using Boltzmann transport theory and first-principles calculations as a function of Fermi energy and crystal orientation. We find that the maximum power factor of p-type (n-type) monolayer InSe can be as large as 0.049 (0.043) W/K2m at 300 K in the armchair direction. The excellent thermoelectric performance of monolayer InSe is attributed to both its Seebeck coefficient and electrical conductivity. The large Seebeck coefficient originates from the moderate (about 2 eV) bandgap of monolayer InSe as an indirect gap semiconductor, while its large electrical conductivity is due to its unique two-dimensional density of states (DOS), which consists of an almost constant DOS near the conduction band bottom and a sharp peak near the valence band top.
ISSN:0003-6951
1077-3118
DOI:10.1063/1.5001184