Giant Seebeck effect across the field-induced metal-insulator transition of InAs

Alexandre Jaoui; Gabriel Seyfarth; Carl Willem Rischau; Steffen Wiedmann; Siham Benhabib; Cyril Proust; Kamran Behnia; Benoît Fauqué

doi:10.1038/s41535-020-00296-0

Giant Seebeck effect across the field-induced metal-insulator transition of InAs

Alexandre Jaoui
, Gabriel Seyfarth
, Carl Willem Rischau
, Steffen Wiedmann
, Siham Benhabib
, Cyril Proust
, Kamran Behnia
, Benoît Fauqué

Collège de France
PSL Research University
INSA
LTHE (UMR 5564 CNRS/IRD/Université de Grenoble)
Radboud University

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

Abstract

Lightly doped III–V semiconductor InAs is a dilute metal, which can be pushed beyond its extreme quantum limit upon the application of a modest magnetic field. In this regime, a Mott-Anderson metal–insulator transition, triggered by the magnetic field, leads to a depletion of carrier concentration by more than one order of magnitude. Here, we show that this transition is accompanied by a 200-fold enhancement of the Seebeck coefficient, which becomes as large as 11.3 mV K⁻¹≈130kBe at T = 8 K and B = 29 T. We find that the magnitude of this signal depends on sample dimensions and conclude that it is caused by phonon drag, resulting from a large difference between the scattering time of phonons (which are almost ballistic) and electrons (which are almost localized in the insulating state). Our results reveal a path to distinguish between possible sources of large thermoelectric response in other low-density systems pushed beyond the quantum limit.

Original language	English
Article number	94
Journal	npj Quantum Materials
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s41535-020-00296-0
Publication status	Published - 1 Dec 2020
Externally published	Yes

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title = "Giant Seebeck effect across the field-induced metal-insulator transition of InAs",

abstract = "Lightly doped III–V semiconductor InAs is a dilute metal, which can be pushed beyond its extreme quantum limit upon the application of a modest magnetic field. In this regime, a Mott-Anderson metal–insulator transition, triggered by the magnetic field, leads to a depletion of carrier concentration by more than one order of magnitude. Here, we show that this transition is accompanied by a 200-fold enhancement of the Seebeck coefficient, which becomes as large as 11.3 mV K−1≈130kBe at T = 8 K and B = 29 T. We find that the magnitude of this signal depends on sample dimensions and conclude that it is caused by phonon drag, resulting from a large difference between the scattering time of phonons (which are almost ballistic) and electrons (which are almost localized in the insulating state). Our results reveal a path to distinguish between possible sources of large thermoelectric response in other low-density systems pushed beyond the quantum limit.",

author = "Alexandre Jaoui and Gabriel Seyfarth and Rischau, \{Carl Willem\} and Steffen Wiedmann and Siham Benhabib and Cyril Proust and Kamran Behnia and Beno{\^i}t Fauqu{\'e}",

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T1 - Giant Seebeck effect across the field-induced metal-insulator transition of InAs

AU - Jaoui, Alexandre

AU - Seyfarth, Gabriel

AU - Rischau, Carl Willem

AU - Wiedmann, Steffen

AU - Benhabib, Siham

AU - Proust, Cyril

AU - Behnia, Kamran

AU - Fauqué, Benoît

PY - 2020/12/1

Y1 - 2020/12/1

N2 - Lightly doped III–V semiconductor InAs is a dilute metal, which can be pushed beyond its extreme quantum limit upon the application of a modest magnetic field. In this regime, a Mott-Anderson metal–insulator transition, triggered by the magnetic field, leads to a depletion of carrier concentration by more than one order of magnitude. Here, we show that this transition is accompanied by a 200-fold enhancement of the Seebeck coefficient, which becomes as large as 11.3 mV K−1≈130kBe at T = 8 K and B = 29 T. We find that the magnitude of this signal depends on sample dimensions and conclude that it is caused by phonon drag, resulting from a large difference between the scattering time of phonons (which are almost ballistic) and electrons (which are almost localized in the insulating state). Our results reveal a path to distinguish between possible sources of large thermoelectric response in other low-density systems pushed beyond the quantum limit.

AB - Lightly doped III–V semiconductor InAs is a dilute metal, which can be pushed beyond its extreme quantum limit upon the application of a modest magnetic field. In this regime, a Mott-Anderson metal–insulator transition, triggered by the magnetic field, leads to a depletion of carrier concentration by more than one order of magnitude. Here, we show that this transition is accompanied by a 200-fold enhancement of the Seebeck coefficient, which becomes as large as 11.3 mV K−1≈130kBe at T = 8 K and B = 29 T. We find that the magnitude of this signal depends on sample dimensions and conclude that it is caused by phonon drag, resulting from a large difference between the scattering time of phonons (which are almost ballistic) and electrons (which are almost localized in the insulating state). Our results reveal a path to distinguish between possible sources of large thermoelectric response in other low-density systems pushed beyond the quantum limit.

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Giant Seebeck effect across the field-induced metal-insulator transition of InAs

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