All-Optical Switching Using the Quantum Zeno Effect and Two-Photon Absorption

TL;DR

This paper demonstrates how the quantum Zeno effect, facilitated by two-photon absorption in rubidium vapor, can be used to implement classical all-optical logic gates with low power operation.

Contribution

It extends the application of the quantum Zeno effect from quantum to classical logic gate implementation using two-photon absorption.

Findings

Quantum Zeno effect enables classical optical switching.

Rubidium vapor allows low-power device operation.

Switching times are analyzed dynamically.

Abstract

We have previously shown that the quantum Zeno effect can be used to implement quantum logic gates for quantum computing applications, where the Zeno effect was produced using a strong two-photon absorbing medium. Here we show that the Zeno effect can also be used to implement classical logic gates whose inputs and outputs are high-intensity fields (coherent states). The operation of the devices can be understood using a quasi-static analysis, and their switching times are calculated using a dynamic approach. The two-photon absorption coefficient of rubidium vapor is shown to allow operation of these devices at relatively low power levels.