COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices
Qubits for quantum computer applications can be based on many different types of architectures and operational principles. One possible quantum nanostructure which has been known to allow properties such as spin-readout is Quantum Dots (QD), showing promise as potential future scalable and int...
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sg-ntu-dr.10356-1484892023-02-28T23:15:24Z COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices Lai, Marcus Kar Fai Bent Weber School of Physical and Mathematical Sciences b.weber@ntu.edu.sg Science::Physics::Descriptive and experimental mechanics Qubits for quantum computer applications can be based on many different types of architectures and operational principles. One possible quantum nanostructure which has been known to allow properties such as spin-readout is Quantum Dots (QD), showing promise as potential future scalable and integrable semiconductor qubit architectures. With certain advantages over highly researched materials such as Gallium Arsenide (GaAs) and Doped crystal structures, Transition Metal Dichalcogenide (TMDC) Quantum Dot (QD) devices recently gained much interest, heavily spurring research efforts towards geometry, fabrication, and characterisation. Devices that have been made, using these 2D materials as 2-Dimensional Electron Gas (2DEG) interfaces, combined with multi-contact lateral electrostatic confinements, show coulomb blockade oscillation and coulomb diamond characteristics from Source-Drain (SD) and Plunger gate (P) voltage sweeps. These are hallmarks of QD formation, having been demonstrated in many different multi-contact geometries. In this investigation, electrostatic COMSOL Multiphysics simulation is tested then applied for a “transistor-like” split-gate geometry. Simultaneously, apparatus for Room Temperature (RT) and 4 Kelvin (4K) electrical characterisation have been reworked. 4K electrical characterisation of a newly fabricated split-gate MoS2 device suggests formation of QDs within the SD-channel. Purely electrostatic simulations weakly suggest evidence for possible QD formation sites. Therefore, this investigation hopes to contribute towards predictive modelling for potential QD formation sites, based on geometric and electrostatic potential simulation. Geometric optimisation attempts are mentioned at the end of this paper. Bachelor of Science in Applied Physics 2021-04-28T02:07:22Z 2021-04-28T02:07:22Z 2021 Final Year Project (FYP) Lai, M. K. F. (2021). COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/148489 https://hdl.handle.net/10356/148489 en application/pdf Nanyang Technological University |
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Science::Physics::Descriptive and experimental mechanics Lai, Marcus Kar Fai COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices |
| description |
Qubits for quantum computer applications can be based on many different types of architectures
and operational principles. One possible quantum nanostructure which has been known to allow
properties such as spin-readout is Quantum Dots (QD), showing promise as potential future
scalable and integrable semiconductor qubit architectures. With certain advantages over highly
researched materials such as Gallium Arsenide (GaAs) and Doped crystal structures, Transition
Metal Dichalcogenide (TMDC) Quantum Dot (QD) devices recently gained much interest,
heavily spurring research efforts towards geometry, fabrication, and characterisation. Devices that
have been made, using these 2D materials as 2-Dimensional Electron Gas (2DEG) interfaces,
combined with multi-contact lateral electrostatic confinements, show coulomb blockade
oscillation and coulomb diamond characteristics from Source-Drain (SD) and Plunger gate (P)
voltage sweeps. These are hallmarks of QD formation, having been demonstrated in many
different multi-contact geometries. In this investigation, electrostatic COMSOL Multiphysics
simulation is tested then applied for a “transistor-like” split-gate geometry. Simultaneously,
apparatus for Room Temperature (RT) and 4 Kelvin (4K) electrical characterisation have
been reworked. 4K electrical characterisation of a newly fabricated split-gate MoS2 device
suggests formation of QDs within the SD-channel. Purely electrostatic simulations weakly
suggest evidence for possible QD formation sites. Therefore, this investigation hopes to
contribute towards predictive modelling for potential QD formation sites, based on geometric
and electrostatic potential simulation. Geometric optimisation attempts
are mentioned at the end of this paper. |
| author2 |
Bent Weber |
| author_facet |
Bent Weber Lai, Marcus Kar Fai |
| format |
Final Year Project |
| author |
Lai, Marcus Kar Fai |
| author_sort |
Lai, Marcus Kar Fai |
| title |
COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices |
| title_short |
COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices |
| title_full |
COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices |
| title_fullStr |
COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices |
| title_full_unstemmed |
COMSOL simulation of electrostatic confinements in nanoscale TMDC QD devices |
| title_sort |
comsol simulation of electrostatic confinements in nanoscale tmdc qd devices |
| publisher |
Nanyang Technological University |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/148489 |
| _version_ |
1759855835467481088 |