Doppler-insensitive two-qubit controlled-PHASE gate protocol with dual-pulse off-resonant modulated driving for neutral atoms

TL;DR

This paper presents a Doppler-insensitive two-qubit controlled-PHASE gate protocol for neutral atoms, utilizing dual-pulse off-resonant modulated driving to improve fidelity and robustness against atomic motion.

Contribution

It introduces a novel dual-pulse off-resonant driving scheme that enhances gate fidelity by reducing sensitivity to atomic motion and errors, advancing neutral atom quantum computing.

Findings

Gate fidelity remains high over a range of atomic velocities.

The protocol avoids population leakage and rotation errors.

It does not require individual site addressing or precise blockade shift values.

Abstract

For neutral atom qubits, the residual thermal motion of the cold atoms constitutes a major challenge that limits the accessible two-qubit gate fidelity. Recently, an interesting type of two-qubit controlled-PHASE quantum gate protocol has been introduced for neutral atom qubit platform, which relies upon off-resonant modulated driving and Rydberg blockade effect. Building upon this progress, we have further developed an upgrade in the form of dual-pulse off-resonant modulated driving. Besides the inherent advantages of avoiding shelving population in Rydberg levels, not necessarily requiring individual site addressing, not sensitive to the exact value of blockade shift while suppressing population leakage error and rotation error, the major new feature of this protocol is Doppler-insensitive. In principle, the gate fidelity remains reasonably high over a relatively significant velocity range of the qubit atoms. Moreover, we anticipate that this protocol will inspire future improvements in quantum gate protocols for other types of qubit platforms, and its strategies may find applications in the area of quantum optimal control.