Two carrier temperatures non-equilibrium generalized Planck law for semiconductors

François Gibelli; Laurent Lombez; Jean François Guillemoles

doi:10.1016/j.physb.2016.06.006

Two carrier temperatures non-equilibrium generalized Planck law for semiconductors

François Gibelli, Laurent Lombez, Jean François Guillemoles

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

Abstract

Planck's law of radiation describes the light emitted by a blackbody. This law has been generalized in the past for the case of a non-blackbody material having a quasi Fermi-level splitting: the lattice of the material and the carriers are then considered in an isothermal regime. Hot carrier spectroscopy deals with carriers out of the isothermal regime, as their respective temperatures (THe ≠ THh) are considered to be different than that of the lattice (_TL). Here we show that Fermi-Dirac distribution temperature for each type of carrier still determine an effective radiation temperature: an explicit relationship is given involving the effective masses. Moreover, we show how to determine, in principle with an additional approximation, the carrier temperatures (THe,THh) and the corresponding absolute electrochemical potentials from photoluminescence measurements.

Original language	English
Pages (from-to)	7-14
Number of pages	8
Journal	Physica B: Physics of Condensed Matter
Volume	498
DOIs	https://doi.org/10.1016/j.physb.2016.06.006
Publication status	Published - 1 Oct 2016

Keywords

Absolute electrochemical potentials
Emission temperature
Generalized Planck's law
Hot carrier
Non-equilibrium carriers
Photoluminescence

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10.1016/j.physb.2016.06.006

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title = "Two carrier temperatures non-equilibrium generalized Planck law for semiconductors",

abstract = "Planck's law of radiation describes the light emitted by a blackbody. This law has been generalized in the past for the case of a non-blackbody material having a quasi Fermi-level splitting: the lattice of the material and the carriers are then considered in an isothermal regime. Hot carrier spectroscopy deals with carriers out of the isothermal regime, as their respective temperatures (THe ≠ THh) are considered to be different than that of the lattice (TL). Here we show that Fermi-Dirac distribution temperature for each type of carrier still determine an effective radiation temperature: an explicit relationship is given involving the effective masses. Moreover, we show how to determine, in principle with an additional approximation, the carrier temperatures (THe,THh) and the corresponding absolute electrochemical potentials from photoluminescence measurements.",

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AU - Gibelli, François

AU - Lombez, Laurent

AU - Guillemoles, Jean François

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N2 - Planck's law of radiation describes the light emitted by a blackbody. This law has been generalized in the past for the case of a non-blackbody material having a quasi Fermi-level splitting: the lattice of the material and the carriers are then considered in an isothermal regime. Hot carrier spectroscopy deals with carriers out of the isothermal regime, as their respective temperatures (THe ≠ THh) are considered to be different than that of the lattice (TL). Here we show that Fermi-Dirac distribution temperature for each type of carrier still determine an effective radiation temperature: an explicit relationship is given involving the effective masses. Moreover, we show how to determine, in principle with an additional approximation, the carrier temperatures (THe,THh) and the corresponding absolute electrochemical potentials from photoluminescence measurements.

AB - Planck's law of radiation describes the light emitted by a blackbody. This law has been generalized in the past for the case of a non-blackbody material having a quasi Fermi-level splitting: the lattice of the material and the carriers are then considered in an isothermal regime. Hot carrier spectroscopy deals with carriers out of the isothermal regime, as their respective temperatures (THe ≠ THh) are considered to be different than that of the lattice (TL). Here we show that Fermi-Dirac distribution temperature for each type of carrier still determine an effective radiation temperature: an explicit relationship is given involving the effective masses. Moreover, we show how to determine, in principle with an additional approximation, the carrier temperatures (THe,THh) and the corresponding absolute electrochemical potentials from photoluminescence measurements.

KW - Absolute electrochemical potentials

KW - Emission temperature

KW - Generalized Planck's law

KW - Hot carrier

KW - Non-equilibrium carriers

KW - Photoluminescence

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DO - 10.1016/j.physb.2016.06.006

M3 - Article

AN - SCOPUS:84976513723

SN - 0921-4526

VL - 498

SP - 7

EP - 14

JO - Physica B: Physics of Condensed Matter

JF - Physica B: Physics of Condensed Matter

ER -

Two carrier temperatures non-equilibrium generalized Planck law for semiconductors

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Keywords

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