Multimode and Random-Access Optical Quantum Memory via Adiabatic Phase Imprinting

TL;DR

This paper introduces a novel quantum memory protocol using adiabatic phase imprinting with RAP pulses, enabling efficient, high-fidelity storage and random access of multiple photonic qubits across spectral modes in rare-earth ion-doped crystals.

Contribution

It presents a new adiabatic rephasing protocol employing RAP pulses that improves multimode capacity and fidelity in quantum memory, surpassing traditional non-adiabatic methods.

Findings

Successfully stored and retrieved multiple photonic modes.

Achieved optical random access memory across eight spectral modes.

Reduced rephasing pulse intensity for higher efficiency.

Abstract

A photonic quantum memory capable of simultaneously storing multiple qubits and subsequently recalling any randomly selected subset of the qubits, is essential for large-scale quantum networking and computing. Such functionality, akin to classical Random-Access Memory (RAM), has proven difficult to implement due to the absence of a versatile random-access mechanism and limited multimode capacity in existing quantum memory protocols. A potential path to developing the quantum analog to RAM is offered by photon-echo protocols in rare-earth ion-doped materials, such as Revival Of Silenced Echo. These can utilize optical rephasing pulses to selectively read-out frequency multiplexed photonic qubits within an inhomogeneously broadened optical transition. However, the conventional non-adiabatic nature of the rephasing pulses requires intense, short-duration pulses, impeding their fidelity and multimode capacity. To address these critical limitations, we introduce an alternate protocol that employs Rapid Adiabatic Passage (RAP) rephasing pulses, to realize quantum memory, which invokes phase-imprints to suppress undesirable echoes. Using the optical transitions of a $^{171}{\rm Yb}^{3+}$:${\rm Y}_2{\rm SiO}_5$ crystal, we demonstrate the storage and retrieval of multiple intricate spectro-temporally photonic modes and achieve optical random access memory across eight distinct spectral modes. This protocol yields greatly enhanced mode-mapping versatility while substantially lowering the required rephasing pulse intensity, providing a more efficient and reliable approach for high-fidelity qubit storage and retrieval.