Implications of the spin-orbit interaction for singlet-triplet qubits in silicon
Abstract not provided.
Publications
Search results
Jump to search filtersAC controlled spin-orbit qubits
Abstract not provided.
Implications of the Spin-Orbit Effect for Singlet-Triplet Qubit Operation
Abstract not provided.
Current-Biased SET-HBT Cryogenic Preamplifier for High-Fidelity Single-Shot Spin Readout
Abstract not provided.
All-electrical universal control of a double quantum dot qubit in silicon MOS
Abstract not provided.
Single Shot Pauli-Blockade in Lithographically Formed Few Electron MOS Double-Quantum-Dot Using a Single Layer Design
Abstract not provided.
Implications of the spin-orbit effect for singlet-triplet qubit operation
Abstract not provided.
Probing low noise at the MOS interface with a Spin-Orbit Singlet-Triplet Qubit
Abstract not provided.
Theory of a silicon MOS spin-orbit singlet-triplet qubit
Abstract not provided.
Probing low noise at the MOS interface with a spin-orbit qubit
Abstract not provided.
Probing low noise at the MOS interface with a spin-orbit qubit
arXiv.org
The silicon metal-oxide-semiconductor (MOS) material system is technologically important for the implementation of electron spin-based quantum information technologies. Researchers predict the need for an integrated platform in order to implement useful computation, and decades of advancements in silicon microelectronics fabrication lends itself to this challenge. However, fundamental concerns have been raised about the MOS interface (e.g. trap noise, variations in electron g-factor and practical implementation of multi-QDs). Furthermore, two-axis control of silicon qubits has, to date, required the integration of non-ideal components (e.g. microwave strip-lines, micro-magnets, triple quantum dots, or introduction of donor atoms). In this paper, we introduce a spin-orbit (SO) driven singlet- triplet (ST) qubit in silicon, demonstrating all-electrical two-axis control that requires no additional integrated elements and exhibits charge noise properties equivalent to other more model, but less commercially mature, semiconductor systems. We demonstrate the ability to tune an intrinsic spin-orbit interface effect, which is consistent with Rashba and Dresselhaus contributions that are remarkably strong for a low spin-orbit material such as silicon. The qubit maintains the advantages of using isotopically enriched silicon for producing a quiet magnetic environment, measuring spin dephasing times of 1.6 μs using 99.95% 28Si epitaxy for the qubit, comparable to results from other isotopically enhanced silicon ST qubit systems. This work, therefore, demonstrates that the interface inherently provides properties for two-axis control, and the technologically important MOS interface does not add additional detrimental qubit noise. isotopically enhanced silicon ST qubit systems
Comparing SiGe HBT Amplifier Circuits for Fast Single-shot Spin Readout
Abstract not provided.
Mixing-Chamber Preamplifier for Spin Qubit Readout
Abstract not provided.
Magnetic field and angular dependent singlet-triplet rotations in a donor-quantum dot qubit
Abstract not provided.
Results 51–64 of 64