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Abstract:
Recently, integrated photonics has brought new capabilities to electron microscopy and been used to demonstrate efficient electron phase modulation and electron-photon correlations. Here, we quantitatively analyze the interaction strength between a free electron and a photonic integrated circuit with a heterogeneous structure. We adopt a dissipative QED treatment and show that with proper electron beam positioning and waveguide geometry, one can achieve near-unity coupling ideality to a well-defined spatial-temporal waveguide mode. Furthermore, we show that the frequency and waveform of the coupled mode can be tailored to the application. These features show that photonic integrated waveguides are a promising platform for free-electron quantum optics with applications like high-fidelity electron-photon entanglement, heralded single-electron and photon state synthesis.