Near-Perfect Single-Photon Source via Ultrastrong Coupling
Abstract
Deterministic single-photon sources are indispensable core devices for quantum information technology, yet high-performance implementation remains a long-standing bottleneck for linear optical quantum computing. We propose a feasible scheme for deterministic single-photon emission based on a -type three-level atom coupled to a single-mode cavity, driven by two classical external fields, which is adaptable to both strong and ultrastrong cavity-atom coupling regimes. Under continuous-wave driving, the system achieves excellent single-photon characteristics: the normalized equal-time second-order correlation function reaches g(2)(0)10-6, with a photon indistinguishability of 98.73\% and a state purity of 99.95\% in the strong coupling regime, while the ultrastrong coupling regime further suppresses G(2)(0)10-8, yielding an indistinguishability of 99.10\% and a purity of 99.99\%. For pulsed driving in the ultrastrong coupling regime, the source realizes superior performance, with an emission efficiency, indistinguishability, and purity of 99.96\%, 98.98\%, and 99.99\% under resonant conditions, and 100\%, 95.91\%, and 99.93\% under detuned conditions, respectively. The near-ideal optical performance of the proposed scheme provides a viable route for constructing high-quality deterministic single-photon sources, which offers a promising solution to the limitations of conventional single-photon devices and facilitates the further development of quantum information science and fundamental quantum optical research.
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