Scalable high-fidelity and near-deterministic preparation of large photon-number states

TL;DR

This paper presents a scalable, high-fidelity method for preparing large photon-number states using native spin-oscillator operations, achieving near-deterministic success at hundreds of photons.

Contribution

The authors introduce a control protocol that combines Jaynes--Cummings interactions with phase-space displacements for efficient large photon-number state generation.

Findings

Photon-number states with fidelity >0.95 for hundreds of photons

Success probability exceeds 0.90, near-deterministic operation

Protocol is robust against noise and dissipation

Abstract

The scalable preparation of large photon-number (Fock) states is a long-standing frontier in quantum science, with direct implications for quantum metrology and bosonic quantum information processing. Despite substantial progress at small photon numbers, extending state generation to large photon numbers while maintaining high fidelity and operating deterministically remains a significant challenge. Here we demonstrate a scalable and experimentally accessible control protocol for generating large photon-number states using only native spin--oscillator operations. The protocol alternates Jaynes--Cummings interactions with phase-space displacements to imprint photon-number--dependent phases and convert them into selective interference in photon-number space. It already achieves high preparation fidelity unconditionally, while an optional final qubit projection removes residual qubit--field correlations and further enhances the fidelity. Conditioned on this final projection, photon-number state preparation with fidelities exceeding $0.95$ is achieved for photon numbers in the few-hundred regime, with a success probability exceeding $0.90$, placing the protocol in a near-deterministic operating regime. The resulting control sequences remain shallow and are robust against detuning, control noise, and experimentally relevant dissipation. Our results establish a practical route to scalable, high-fidelity photon-number state preparation at large photon numbers and provide a versatile interference-engineering toolbox for nonclassical bosonic state synthesis.