Quantum dot and semiconductor research with the quantum physics group at NRC
APA
(). Quantum dot and semiconductor research with the quantum physics group at NRC. SNOLAB. https://scivideos.org/snolab/1010
MLA
Quantum dot and semiconductor research with the quantum physics group at NRC. SNOLAB, , https://scivideos.org/snolab/1010
BibTex
@misc{ scivideos_1010, doi = {}, url = {https://scivideos.org/snolab/1010}, author = {}, keywords = {Physics}, language = {en}, title = {Quantum dot and semiconductor research with the quantum physics group at NRC}, publisher = {SNOLAB}, year = {}, month = {}, note = {1010 see, \url{https://scivideos.org/snolab/1010}} }
Abstract
Spin and hybrid spin-charge qubits have been a long-term goal of the fields of Spintronics and Quantum Information. Such a qubit in an array would ideally interact separately from other qubits and “tunably” with a Microwave field. In this way, a single qubit may be turned “on”, interact with its environment to acquire information (for example, flip a spin state), and be turned “off” so it may indefinitely store that information. The necessary tunability for such a task has been demonstrated in a single hole of a p-type GaAs/AlGaAs Double Quantum Dot (DQD) with strong Spin-Orbit Interaction (SOI), in which the interdot tunnel coupling is strong so that hybridized quantum molecular states form [1]. If the interdot coupling is reduced, this form of tunability is lost. However, a new phenomenon may permit tunability: the weak interdot coupling gives rise to distinct dot-specific quantum dot g-factors smoothly connected by the spin-orbit interaction. By sweeping gate voltages such that we choose which dot is being probed, a qubit may be turned “on” or “off” as necessary. During my work terms with the low-temperature Quantum Physics Group at the National Research Council of Canada, I investigated the appearance of dot-specific g-factors and partially characterized the double quantum dot system using a theoretical model.