All-electrical control of hole singlet-triplet spin qubits at low
leakage points
- URL: http://arxiv.org/abs/2107.12622v1
- Date: Tue, 27 Jul 2021 06:34:26 GMT
- Title: All-electrical control of hole singlet-triplet spin qubits at low
leakage points
- Authors: Philipp M. Mutter and Guido Burkard
- Abstract summary: We study the effect of the spin-orbit interaction on heavy holes confined in a double quantum dot in the presence of a magnetic field of arbitrary direction.
It is demonstrated that these effects may counteract in such a way as to cancel the coupling at certain detunings and tilting angles of the magnetic field.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We study the effect of the spin-orbit interaction on heavy holes confined in
a double quantum dot in the presence of a magnetic field of arbitrary
direction. Rich physics arise as the two hole states of different spin are not
only coupled by the spin-orbit interaction but additionally by the effect of
site-dependent anisotropic $g$ tensors. It is demonstrated that these effects
may counteract in such a way as to cancel the coupling at certain detunings and
tilting angles of the magnetic field. This feature may be used in
singlet-triplet qubits to avoid leakage errors and implement an electrical
spin-orbit switch, suggesting the possibility of task-tailored two-axes
control. Additionally, we investigate systems with a strong spin-orbit
interaction at weak magnetic fields. By exact diagonalization of the dominant
Hamiltonian we find that the magnetic field may be chosen such that the qubit
ground state is mixed only within the logical subspace for realistic system
parameters, hence reducing leakage errors and providing reliable control over
the qubit.
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