Single-qubit operations in the double-donor structure driven by optical and voltage pulses

TL;DR

This paper theoretically investigates how laser and voltage pulses can control a charge qubit in a double-donor semiconductor structure, enabling arbitrary single-qubit rotations through resonant and Raman-like transitions.

Contribution

It demonstrates the feasibility of performing arbitrary single-qubit operations in a double-donor system using optical and voltage pulses, a novel approach for quantum control.

Findings

Arbitrary single-qubit rotations can be realized in the system.

Quantum dynamics are driven by resonant and Raman-like transitions.

Voltage pulses induce phase shifts between qubit states.

Abstract

We study theoretically the quantum dynamics of an electron in the singlyionized double-donor structure in the semiconductor host under the influence of laser pulses whose frequencies are close to structure resonant frequencies. This system can be used as a charge qubit where the logical states are defined by the lowest two energy states of the remaining valence electron localized around one or another donor. The quantum operations are performed via resonant or Raman-like transitions between the localized (qubit) states and the excited states delocalized over the structure, combined with phase shifts between qubit states generated by voltage pulses. The possibility of realization of arbitrary single-qubit rotations is demonstrated.