Topological phase transition and evolution of edge states in In-rich InGaN/GaN quantum wells under hydrostatic pressure. (12th December 2016)
- Record Type:
- Journal Article
- Title:
- Topological phase transition and evolution of edge states in In-rich InGaN/GaN quantum wells under hydrostatic pressure. (12th December 2016)
- Main Title:
- Topological phase transition and evolution of edge states in In-rich InGaN/GaN quantum wells under hydrostatic pressure
- Authors:
- Łepkowski, S P
Bardyszewski, W - Abstract:
- Abstract: Combining thek · p method with the third-order elasticity theory, we perform a theoretical study of the pressure-induced topological phase transition and the pressure evolution of topologically protected edge states in InN/GaN and In-rich InGaN/GaN quantum wells. We show that for a certain range of the quantum well parameters, thanks to a negative band gap pressure coefficient, it is possible to continuously drive the system from the normal insulator state through the topological insulator into the semimetal phase. The critical pressure for the topological phase transition depends not only on the quantum well thickness but also on the width of the Hall bar, which determines the coupling between the edge states localized at the opposite edges. We also find that in narrow Hall bar structures, near the topological phase transition, a significant Rashba-type spin splitting of the lower and upper branches of the edge state dispersion curve appears. This effect originates from the lack of the mirror symmetry of the quantum well potential caused by the built-in electric field, and can be suppressed by increasing the Hall bar width. When the pressure increases, the energy dispersion of the edge states becomes more parabolic-like and the spin splitting decreases. A further increase of pressure leads to the transition to a semimetal phase, which occurs due to the closure of the indirect 2D bulk band gap. The difference between the critical pressure at which the systemAbstract: Combining thek · p method with the third-order elasticity theory, we perform a theoretical study of the pressure-induced topological phase transition and the pressure evolution of topologically protected edge states in InN/GaN and In-rich InGaN/GaN quantum wells. We show that for a certain range of the quantum well parameters, thanks to a negative band gap pressure coefficient, it is possible to continuously drive the system from the normal insulator state through the topological insulator into the semimetal phase. The critical pressure for the topological phase transition depends not only on the quantum well thickness but also on the width of the Hall bar, which determines the coupling between the edge states localized at the opposite edges. We also find that in narrow Hall bar structures, near the topological phase transition, a significant Rashba-type spin splitting of the lower and upper branches of the edge state dispersion curve appears. This effect originates from the lack of the mirror symmetry of the quantum well potential caused by the built-in electric field, and can be suppressed by increasing the Hall bar width. When the pressure increases, the energy dispersion of the edge states becomes more parabolic-like and the spin splitting decreases. A further increase of pressure leads to the transition to a semimetal phase, which occurs due to the closure of the indirect 2D bulk band gap. The difference between the critical pressure at which the system becomes semimetallic, and the pressure for the topological phase transition, correlates with the variation of the pressure coefficient of the band gap in the normal insulator state. … (more)
- Is Part Of:
- Journal of physics. Volume 29:Number 5(2017)
- Journal:
- Journal of physics
- Issue:
- Volume 29:Number 5(2017)
- Issue Display:
- Volume 29, Issue 5 (2017)
- Year:
- 2017
- Volume:
- 29
- Issue:
- 5
- Issue Sort Value:
- 2017-0029-0005-0000
- Page Start:
- Page End:
- Publication Date:
- 2016-12-12
- Subjects:
- topological insulators -- group-III nitrides -- hydrostatic pressure
Condensed matter -- Periodicals
Matière condensée -- Périodiques
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Electronic journals
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530.4105 - Journal URLs:
- http://www.iop.org/Journals/cm ↗
http://iopscience.iop.org/0953-8984/ ↗
http://ioppublishing.org/ ↗ - DOI:
- 10.1088/1361-648X/29/5/055702 ↗
- Languages:
- English
- ISSNs:
- 0953-8984
- Deposit Type:
- Legaldeposit
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