学术文献库

The design of scalable quantum computers will benefit from predictive models for qubit performance that consider the design and layout of the qubit devices. This approach, has recently been adopted for superconducting qubits, but has received little attention for spin qubits in semiconductors. Here, we employ models for both the device and the quantum mechanical states in the valence band to theoretically investigate the properties of hole spin qubits in laterally gated quantum dots in group-IV materials, which have received significant recent attention. We find that device design impacts qubit properties in unexpected ways. First, the presence of optimal operation points where coherence times are long and qubits can be rapidly manipulated results not only from gate-voltage-induced changes to the Rashba coefficient, but also from gate-voltage-induced changes to quantum dot radius in real devices, which impacts g-factor even when inversion symmetry is preserved (Rashba coupling is zero). Second, the qubit electric manipulation is substantially higher in the realistic anharmonic potential, by an order of magnitude in the device design we consider, compared with a harmonic potential assumption, because the transverse electric dipole of the qubit depends on electrically mediated couplings to many excited states. Finally, we show that the rapid electric drive, compatible with long coherence times, can be achieved in the single-hole regime, with and without strain. These results establish the need for realistic description of both the device and the quantum mechanical states to support the design of spin qubit devices, identify new ways to control hole qubit properties.