Deterministic photonic quantum computation in a synthetic time dimension

TL;DR

This paper introduces a scalable, resource-efficient photonic quantum computer architecture using a single atom and optical switches to create a synthetic time dimension, enabling deterministic quantum operations without many emitters.

Contribution

The authors propose a novel photonic quantum computing architecture that uses a single atom and optical switches to implement arbitrary quantum circuits deterministically.

Findings

Operates deterministically without many quantum emitters.

Requires no single-photon detectors.

Machine size is independent of circuit depth.

Abstract

Photonics offers unique advantages as a substrate for quantum information processing, but imposes fundamental scalability challenges. Nondeterministic schemes impose massive resource overheads, while deterministic schemes require prohibitively many identical quantum emitters to realize sizeable quantum circuits. Here we propose a scalable architecture for a photonic quantum computer which needs minimal quantum resources to implement any quantum circuit: a single coherently controlled atom. Optical switches endow a photonic quantum state with a synthetic time dimension by modulating photon-atom couplings. Quantum operations applied to the atomic qubit can be teleported onto the photonic qubits via projective measurement, and arbitrary quantum circuits can be compiled into a sequence of these teleported operators. This design negates the need for many identical quantum emitters to be integrated into a photonic circuit and allows effective all-to-all connectivity between photonic qubits. The proposed device has a machine size which is independent of quantum circuit depth, does not require single-photon detectors, operates deterministically, and is robust to experimental imperfections.