Fine tuning of quantum operations performed via Raman transitions

TL;DR

This paper proposes a method to fine-tune quantum operations using Raman transitions in a Λ system, enhancing fidelity by identifying optimal detunings and analyzing the effects of cavity damping and spontaneous emission.

Contribution

It introduces a novel approach for improving quantum operation fidelity via detailed analysis of dressed states and perturbative solutions without adiabatic elimination.

Findings

High-fidelity detunings identified for specific quantum operations

Spontaneous emission can stabilize quantum operations

Analytical and numerical solutions validate the approach

Abstract

A scheme for fine tuning of quantum operations to improve their performance is proposed. A quantum system in $\Lambda$ configuration with two-photon Raman transitions is considered without adiabatic elimination of the excited (intermediate) state. Conditional dynamics of the system is studied with focus on improving fidelity of quantum operations. In particular, the $\pi$ pulse and $\pi/2$ pulse quantum operations are considered. The dressed states for the atom-field system, with an atom driven on one transition by a classical field and on the other by a quantum cavity field, are found. A discrete set of detunings is given for which high fidelity of desired states is achieved. Analytical solutions for the quantum state amplitudes are found in the first order perturbation theory with respect to the cavity damping rate $\kappa$ and the spontaneous emission rate $\gamma$. Numerical solutions for higher values of $\kappa$ and $\gamma$ indicate a stabilizing role of spontaneous emission in the $\pi$ and $\pi/2$ pulse quantum operations. The idea can also be applied for excitation pulses of different shapes.