Gain-Assisted and Dynamically Controlled Optical Bistability for Quantum Logic Gate Applications

TL;DR

This paper explores how gain-assisted optical bistability in cold atomic systems, controlled by structured light, can be used to develop scalable quantum logic gates like CNOT for quantum information processing.

Contribution

It introduces a novel scheme combining gain, structured light, and atomic coherence to enhance optical bistability for quantum gate applications.

Findings

Gain reduces the threshold for optical bistability.

Orbital angular momentum influences bistable behavior.

Proposed scheme enables CNOT gate via dynamic bistability control.

Abstract

The propagation of a probe field in an N-type four level cold atomic system is investigated under the influence of multiple coherent fields. Coherent control of quantum interference enables switching of the probe field between transparency and gain regimes. Subsequent analysis focuses on how the introduction of gain in the probe transition lowers the threshold for optical bistability, thereby enhancing the nonlinear response of the system at reduced input intensities. A detailed analysis of optical bistability is presented, focusing on its threshold, stability, and switching efficiency as functions of field strengths and detunings. Structured light beams, specifically Laguerre Gaussian modes carrying orbital angular momentum, are employed to tailor the bistable characteristics. The impact of Orbital angular momentum through the topological charge and azimuthal phase is shown to significantly influence the bistable behavior. Based on these features, a theoretical scheme is proposed to realize a Controlled-NOT gate via dynamic modulation of bistability. These results highlight the potential of integrating nonlinear optical effects with structured light in cold atomic systems for implementing scalable quantum logic and advancing photonic information processing.