Extended two-temperature model for ultrafast thermal response of band gap materials upon impulsive optical excitation

Taeho Shin; Samuel W. Teitelbaum; Johanna Wolfson; Maria Kandyla; Keith A. Nelson

doi:10.1063/1.4935366

Extended two-temperature model for ultrafast thermal response of band gap materials upon impulsive optical excitation

Taeho Shin, Samuel W. Teitelbaum, Johanna Wolfson, Maria Kandyla, Keith A. Nelson

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

29 Scopus citations

Abstract

Thermal modeling and numerical simulations have been performed to describe the ultrafast thermal response of band gap materials upon optical excitation. A model was established by extending the conventional two-temperature model that is adequate for metals, but not for semiconductors. It considers the time- and space-dependent density of electrons photoexcited to the conduction band and accordingly allows a more accurate description of the transient thermal equilibration between the hot electrons and lattice. Ultrafast thermal behaviors of bismuth, as a model system, were demonstrated using the extended two-temperature model with a view to elucidating the thermal effects of excitation laser pulse fluence, electron diffusivity, electron-hole recombination kinetics, and electron-phonon interactions, focusing on high-density excitation.

Original language	English (US)
Article number	194705
Journal	Journal of Chemical Physics
Volume	143
Issue number	19
DOIs	https://doi.org/10.1063/1.4935366
State	Published - Nov 21 2015
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy(all)
Physical and Theoretical Chemistry

Access to Document

10.1063/1.4935366

Cite this

@article{faea78285baa468cab60f6952f99b762,

title = "Extended two-temperature model for ultrafast thermal response of band gap materials upon impulsive optical excitation",

abstract = "Thermal modeling and numerical simulations have been performed to describe the ultrafast thermal response of band gap materials upon optical excitation. A model was established by extending the conventional two-temperature model that is adequate for metals, but not for semiconductors. It considers the time- and space-dependent density of electrons photoexcited to the conduction band and accordingly allows a more accurate description of the transient thermal equilibration between the hot electrons and lattice. Ultrafast thermal behaviors of bismuth, as a model system, were demonstrated using the extended two-temperature model with a view to elucidating the thermal effects of excitation laser pulse fluence, electron diffusivity, electron-hole recombination kinetics, and electron-phonon interactions, focusing on high-density excitation.",

author = "Taeho Shin and Teitelbaum, {Samuel W.} and Johanna Wolfson and Maria Kandyla and Nelson, {Keith A.}",

note = "Publisher Copyright: {\textcopyright} 2015 AIP Publishing LLC.",

year = "2015",

month = nov,

day = "21",

doi = "10.1063/1.4935366",

language = "English (US)",

volume = "143",

journal = "Journal of Chemical Physics",

issn = "0021-9606",

publisher = "American Institute of Physics Publising LLC",

number = "19",

}

TY - JOUR

T1 - Extended two-temperature model for ultrafast thermal response of band gap materials upon impulsive optical excitation

AU - Shin, Taeho

AU - Teitelbaum, Samuel W.

AU - Wolfson, Johanna

AU - Kandyla, Maria

AU - Nelson, Keith A.

PY - 2015/11/21

Y1 - 2015/11/21

N2 - Thermal modeling and numerical simulations have been performed to describe the ultrafast thermal response of band gap materials upon optical excitation. A model was established by extending the conventional two-temperature model that is adequate for metals, but not for semiconductors. It considers the time- and space-dependent density of electrons photoexcited to the conduction band and accordingly allows a more accurate description of the transient thermal equilibration between the hot electrons and lattice. Ultrafast thermal behaviors of bismuth, as a model system, were demonstrated using the extended two-temperature model with a view to elucidating the thermal effects of excitation laser pulse fluence, electron diffusivity, electron-hole recombination kinetics, and electron-phonon interactions, focusing on high-density excitation.

AB - Thermal modeling and numerical simulations have been performed to describe the ultrafast thermal response of band gap materials upon optical excitation. A model was established by extending the conventional two-temperature model that is adequate for metals, but not for semiconductors. It considers the time- and space-dependent density of electrons photoexcited to the conduction band and accordingly allows a more accurate description of the transient thermal equilibration between the hot electrons and lattice. Ultrafast thermal behaviors of bismuth, as a model system, were demonstrated using the extended two-temperature model with a view to elucidating the thermal effects of excitation laser pulse fluence, electron diffusivity, electron-hole recombination kinetics, and electron-phonon interactions, focusing on high-density excitation.

UR - http://www.scopus.com/inward/record.url?scp=84948461241&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=84948461241&partnerID=8YFLogxK

U2 - 10.1063/1.4935366

DO - 10.1063/1.4935366

M3 - Article

AN - SCOPUS:84948461241

SN - 0021-9606

VL - 143

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

IS - 19

M1 - 194705

ER -

Extended two-temperature model for ultrafast thermal response of band gap materials upon impulsive optical excitation

Abstract

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this