Observation of 2D conduction in ultrathin germanium arsenide field-effect transistors

Alessandro Grillo; Antonio Di Bartolomeo; Francesca Urban; Maurizio Passacantando; Jose M Caridad; Jianbo Sun; Luca Camilli

doi:10.1021/acsami.0c00348

Observation of 2D conduction in ultrathin germanium arsenide field-effect transistors

Alessandro Grillo, Antonio Di Bartolomeo, Francesca Urban, Maurizio Passacantando, Jose M Caridad, Jianbo Sun, Luca Camilli

Materials Chemistry

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

Abstract

We report the fabrication and electrical characterization of germanium arsenide (GeAs) field-effect transistors with ultrathin channels. The electrical transport is investigated in the 20–280 K temperature range, revealing that the p-type electrical conductivity and the field-effect mobility are growing functions of temperature. An unexpected peak is observed in the temperature dependence of the carrier density per area at ∼75 K. Such a feature is explained considering that the increased carrier concentration at higher temperatures and the vertical band bending combined with the gate field lead to the formation of a two-dimensional (2D) conducting channel, limited to few interfacial GeAs layers, which dominates the channel conductance. The conductivity follows the variable-range hopping model at low temperatures and becomes the band-type at higher temperatures when the 2D channel is formed. The formation of the 2D channel is validated through a numerical simulation that shows excellent agreement with the experimental data.

Original language	English
Pages (from-to)	12998-13004
Number of pages	7
Journal	ACS applied materials interfaces
Volume	12
Issue number	11
Early online date	26 Feb 2020
DOIs	https://doi.org/10.1021/acsami.0c00348
Publication status	Published - 18 Mar 2020

Keywords

germanium arsenide
2D conduction
temperature-dependent conduction
field-effect transistors
carrier density
mobility
variable-range hopping

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10.1021/acsami.0c00348

Cite this

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title = "Observation of 2D conduction in ultrathin germanium arsenide field-effect transistors",

abstract = "We report the fabrication and electrical characterization of germanium arsenide (GeAs) field-effect transistors with ultrathin channels. The electrical transport is investigated in the 20–280 K temperature range, revealing that the p-type electrical conductivity and the field-effect mobility are growing functions of temperature. An unexpected peak is observed in the temperature dependence of the carrier density per area at ∼75 K. Such a feature is explained considering that the increased carrier concentration at higher temperatures and the vertical band bending combined with the gate field lead to the formation of a two-dimensional (2D) conducting channel, limited to few interfacial GeAs layers, which dominates the channel conductance. The conductivity follows the variable-range hopping model at low temperatures and becomes the band-type at higher temperatures when the 2D channel is formed. The formation of the 2D channel is validated through a numerical simulation that shows excellent agreement with the experimental data.",

keywords = "germanium arsenide, 2D conduction, temperature-dependent conduction, field-effect transistors, carrier density, mobility, variable-range hopping",

author = "Alessandro Grillo and {Di Bartolomeo}, Antonio and Francesca Urban and Maurizio Passacantando and Caridad, {Jose M} and Jianbo Sun and Luca Camilli",

year = "2020",

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doi = "10.1021/acsami.0c00348",

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T1 - Observation of 2D conduction in ultrathin germanium arsenide field-effect transistors

AU - Grillo, Alessandro

AU - Di Bartolomeo, Antonio

AU - Urban, Francesca

AU - Passacantando, Maurizio

AU - Caridad, Jose M

AU - Sun, Jianbo

AU - Camilli, Luca

PY - 2020/3/18

Y1 - 2020/3/18

N2 - We report the fabrication and electrical characterization of germanium arsenide (GeAs) field-effect transistors with ultrathin channels. The electrical transport is investigated in the 20–280 K temperature range, revealing that the p-type electrical conductivity and the field-effect mobility are growing functions of temperature. An unexpected peak is observed in the temperature dependence of the carrier density per area at ∼75 K. Such a feature is explained considering that the increased carrier concentration at higher temperatures and the vertical band bending combined with the gate field lead to the formation of a two-dimensional (2D) conducting channel, limited to few interfacial GeAs layers, which dominates the channel conductance. The conductivity follows the variable-range hopping model at low temperatures and becomes the band-type at higher temperatures when the 2D channel is formed. The formation of the 2D channel is validated through a numerical simulation that shows excellent agreement with the experimental data.

AB - We report the fabrication and electrical characterization of germanium arsenide (GeAs) field-effect transistors with ultrathin channels. The electrical transport is investigated in the 20–280 K temperature range, revealing that the p-type electrical conductivity and the field-effect mobility are growing functions of temperature. An unexpected peak is observed in the temperature dependence of the carrier density per area at ∼75 K. Such a feature is explained considering that the increased carrier concentration at higher temperatures and the vertical band bending combined with the gate field lead to the formation of a two-dimensional (2D) conducting channel, limited to few interfacial GeAs layers, which dominates the channel conductance. The conductivity follows the variable-range hopping model at low temperatures and becomes the band-type at higher temperatures when the 2D channel is formed. The formation of the 2D channel is validated through a numerical simulation that shows excellent agreement with the experimental data.

KW - germanium arsenide

KW - 2D conduction

KW - temperature-dependent conduction

KW - field-effect transistors

KW - carrier density

KW - mobility

KW - variable-range hopping

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DO - 10.1021/acsami.0c00348

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SN - 1944-8252

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EP - 13004

JO - ACS applied materials interfaces

JF - ACS applied materials interfaces

IS - 11

ER -

Observation of 2D conduction in ultrathin germanium arsenide field-effect transistors

Abstract

Keywords

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