DocumentCode
128834
Title
Investigation of quantum transport in nanoscaled GaN high electron mobility transistors
Author
Baumgartner, Oskar ; Stanojevic, Zlatan ; Filipovic, Lado ; Grill, A. ; Grasser, Tibor ; Kosina, Hans ; Karner, M.
Author_Institution
Inst. for Microelectron., Tech. Univ. Wien, Vienna, Austria
fYear
2014
fDate
9-11 Sept. 2014
Firstpage
117
Lastpage
120
Abstract
In this paper, a comprehensive investigation of quantum transport in nanoscaled gallium nitride (GaN) high electron mobility transistors (HEMTs) is presented. A simulation model for quantum transport in nanodevices on unstructured grids in arbitrary dimension and for arbitrary crystal directions has been developed. The model has been implemented as part of the Vienna-Schrödinger-Poisson simulation and modeling framework. The transport formalism is based on the quantum transmitting boundary method. A new approach to reduce its computational effort has been realized. The model has been used to achieve a consistent treatment of quantization and transport effects in deeply scaled asymmetric GaN HEMTs. The self-consistent electron concentration, conduction band edges and ballistic current have been calculated. The effects of strain relaxation at the heterostructure interfaces on the potential and carrier concentration have been shown.
Keywords
III-V semiconductors; carrier density; conduction bands; gallium compounds; high electron mobility transistors; semiconductor device models; wide band gap semiconductors; GaN; Vienna-Schrodinger-Poisson simulation; arbitrary crystal directions; arbitrary dimension; ballistic current; carrier concentration; computational effort reduction; conduction band edges; deeply-scaled asymmetric gallium nitride HEMT; heterostructure interfaces; modeling framework; nanodevices; nanoscaled gallium nitride HEMT; nanoscaled gallium nitride high-electron mobility transistors; potential concentration; quantization effect; quantum transmitting boundary method; quantum transport; self-consistent electron concentration; simulation model; strain relaxation; transport effect; transport formalism; unstructured grids; Aluminum gallium nitride; Computational modeling; Current density; Gallium nitride; HEMTs; Logic gates; MODFETs;
fLanguage
English
Publisher
ieee
Conference_Titel
Simulation of Semiconductor Processes and Devices (SISPAD), 2014 International Conference on
Conference_Location
Yokohama
ISSN
1946-1569
Print_ISBN
978-1-4799-5287-8
Type
conf
DOI
10.1109/SISPAD.2014.6931577
Filename
6931577
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