Optical Schr\"{o}dinger cat states are non-Gaussian states with applications in quantum technologies, such as for building error-correcting states in quantum computing. Yet the efficient generation of high-fidelity optical Schr\"{o}dinger cat states is an outstanding problem in quantum optics. Here, we propose using squeezed superpositions of zero and two photons, ∣θ⟩=cos(θ/2)∣0⟩+sin(θ/2)∣2⟩, as ingredients for protocols to efficiently generate high-fidelity cat states. We present a protocol using linear optics with success probability P≳50% that can generate cat states of size ∣α∣2=5 with fidelity F>0.99. The protocol relies only on detecting single photons and is remarkably tolerant of loss, with 2% detection loss still achieving F>0.98 for cats with ∣α∣2=5. We also show that squeezed θ states are ideal candidates for nonlinear photon subtraction using a two-level system with near deterministic success probability and fidelity F>0.98 for cat states of size ∣α∣2=5. Schemes for generating θ states using quantum emitters are also presented. Our protocols can be implemented with current state-of-the-art quantum optics experiments.
@article{arxiv.2412.14798,
title = {Efficient optical cat state generation using squeezed few-photon superposition states},
author = {Haoyuan Luo and Sahand Mahmoodian},
journal= {arXiv preprint arXiv:2412.14798},
year = {2026}
}