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arxiv: 2411.12059 · v1 · pith:5ZYHA6BW · submitted 2024-11-18 · quant-ph · physics.optics

Electrically tunable quantum correlations of dipolar polaritons with micrometer-scale blockade radii

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classification quant-ph physics.optics
keywords blockadedipolarphotonpolaritonselectricallyphotonicquantumatomic
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An extreme yet reconfigurable nonlinear response to a single photon by a photonic system is crucial for realizing a universal two-photon gate, an elementary building block for photonic quantum computing. Yet such a response, characterized by the photon blockade effect, has only been achieved in atomic systems or solid states ones that are difficult to scale up. Here we demonstrate electrically tunable partial photon blockade in dipolar waveguide polaritons on a semiconductor chip, measured via photon-correlations. Remarkably, these "dipolar photons" display a two-orders-of-magnitude stronger nonlinearity compared to unpolarized polaritons, with an extracted dipolar blockade radius up to more than 4 $\mu$m, significantly larger than the optical wavelength, and comparable to that of atomic Rydberg polaritons. Furthermore, we show that the dipolar interaction can be electrically switched and locally configured by simply tuning the gate voltage. Finally we show that with a simple modification of the design, a full photon blockade is expected, setting a new route towards scalable, reconfigurable, chip-integrated quantum photonic circuits with strong two-photon nonlinearities.

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Cited by 1 Pith paper

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  1. Modeling the Quantum Photon Statistics in Hybrid Light-Matter Integrated Circuits

    quant-ph 2026-05 unverdicted novelty 6.0

    A new modeling framework represents pulsed polariton waveguide dynamics as a dissipative bosonic quantum circuit to predict antibunching and sub-Poissonian statistics in single and multimode integrated circuit configurations.