Strong Coupling and Single-Photon Nonlinearity in Free-Electron Quantum Optics

Karnieli, Aviv; Roques-Carmes, Charles; Rivera, Nicholas; Fan, Shanhui

doi:10.1021/acsphotonics.4c00908

ACS Photonics

2024

DOI: 10.1021/acsphotonics.4c00908

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Strong Coupling and Single-Photon Nonlinearity in Free-Electron Quantum Optics

Aviv Karnieli,

Charles Roques-Carmes,

Nicholas Rivera

et al.

Abstract: A central challenge in the emerging field of free-electron quantum optics is to achieve strong quantum interaction and single-photon nonlinearity between a flying free electron and a photonic mode. Existing schemes are intrinsically limited by electron diffraction, which puts an upper bound on the interaction length and, therefore, on the strength of quantum coupling and nonlinearity. Here, we propose “free-electron fibers”: effectively one-dimensional photonic systems where free electrons copropagate with two… Show more

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Cited by 3 publications

References 86 publications

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Spontaneous photon emission by shaped quantum electron wavepackets and the QED origin of bunched electron beam superradiance

Zhang,

Ianconescu,

Friedman

et al. 2024

Rep. Prog. Phys.

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It has been shown that the spontaneous emission rate of photons by free electrons, unlike stimulated emission, is independent of the shape or modulation of the quantum electron wavefunction (QEW). Nevertheless, here we show that the quantum state of the emitted photons is non-classical and does depend on the QEW shape. This non-classicality originates from the shape dependent off-diagonal terms of the photon density matrix. This is manifested in the Wigner distribution function and would be observable experimentally through homodyne detection techniques as a squeezing effect. Considering a scheme of electrons interaction with a single microcavity mode, we present a QED formulation of spontaneous emission by multiple modulated QEWs through a build-up process. Our findings indicate that in the case of a density modulated QEWs beam, the phase of the off-diagonal terms of the photon state emitted by the modulated QEWs is the harbinger of bunched beam superradiance, where the spontaneous emission is proportional to N_e^2 . This observation offers a potential for enhancement of other quantum electron interactions with quantum systems by a modulated QEWs beam carrying coherence and quantum properties of the modulation.

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Spontaneous photon emission by shaped quantum electron wavepackets and the QED origin of bunched electron beam superradiance

Zhang,

Ianconescu,

Friedman

et al. 2024

Rep. Prog. Phys.

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show abstract

Spatial electron-photon entanglement

Kazakevich,

Aharon,

Kfir

2024

Phys. Rev. Research

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Free electron beams and their quantum coupling with photons are attracting a rising interest due to the basic questions they address and the innovative technology these particles are involved in, such as microscopy, spectroscopy, and quantum computation. This work proposes spatially encoded coupling, where a dual-rail-like electron (e−) state is entangled to a dual-rail photonic qubit. Thus, it complements the leading current concept of the coupling, which links photonic Fock states with the e− energy. Importantly, we show that a spatial electron-photon pair can reach maximal entanglement and propose mutually unbiased bases for verifying the entanglement in a realistic experimental apparatus. Although the energy-level coupling of an e− beam with photonic excitations is well understood, we show that a naïve approach for extending such interaction from a single to a double path results in a retrocausal paradox. In the future, the atomic scale precision of electron microscopes can harness such position-encoded free-e− entangled qubits for novel quantum sensing and quantum transduction. Published by the American Physical Society 2024

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Subwavelength-modulated silicon photonics for low-energy free-electron-photon interactions

Ates,

Slayton,

Putnam

2024

Opt. Express

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We investigate silicon waveguides with subwavelength-scale modulation for applications in free-electron-photon interactions. The modulation enables velocity matching and efficient interactions between low-energy electrons and co-propagating photons. Specifically, we design a subwavelength-grating (SWG) waveguide for interactions between 23-keV free electrons and ≈1500-nm photons. The SWG waveguide and electron system exhibit a coupling coefficient of |gQu| = 0.23, and as we corroborate with time-domain, particle-in-cell simulations, the system operates as a backward-wave oscillator. Overall, our results show that modulated waveguides could open the door to strong, extended interactions between photons and low-energy (10-keV-scale) electrons, like those typically present in scanning electron microscopes. Additionally, our SWG waveguide design suggests that periodic waveguides could offer intriguing dispersion engineering opportunities for tailoring these interactions.

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Strong Coupling and Single-Photon Nonlinearity in Free-Electron Quantum Optics

Cited by 3 publications

References 86 publications

Spontaneous photon emission by shaped quantum electron wavepackets and the QED origin of bunched electron beam superradiance

Spontaneous photon emission by shaped quantum electron wavepackets and the QED origin of bunched electron beam superradiance

Spatial electron-photon entanglement

Subwavelength-modulated silicon photonics for low-energy free-electron-photon interactions

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