Jaynes-Cummings interaction between low-energy free electrons and cavity photons

Karnieli, Aviv; Fan, Shanhui

doi:10.1126/sciadv.adh2425

Cited by 7 publications

(10 citation statements)

References 88 publications

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“…The use of free electrons for quantum computing has several unique advantages over using photon-based or bound electron–based systems. Free electrons readily propagate information across macroscopic distances and are thus a potential candidate for “flying qubits” ( 68 , 69 ), for instance via the phenomenon of free electron–polariton blockade, made possible by leveraging quantum recoil ( 70 , 71 ). These flying qubits are a core component of designing a potential quantum network or quantum internet, which has motivated implementations thus far in semiconductor systems and bound-electron systems ( 68 ).…”

Section: Discussionmentioning

confidence: 99%

Strongly correlated multielectron bunches from interaction with quantum light

Kumar,

Lim,

Rivera

et al. 2024

Sci. Adv.

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Strongly correlated electron systems are a cornerstone of modern physics, being responsible for groundbreaking phenomena from superconducting magnets to quantum computing. In most cases, correlations in electrons arise exclusively because of Coulomb interactions. In this work, we reveal that free electrons interacting simultaneously with a light field can become highly correlated via mechanisms beyond Coulomb interactions. In the case of two electrons, the resulting Pearson correlation coefficient for the joint probability distribution of the output electron energies is enhanced by more than 13 orders of magnitude compared to that of electrons interacting with the light field in succession (one after another). These highly correlated electrons are the result of momentum and energy exchange between the participating electrons via the external quantum light field. Our findings pave the way to the creation and control of highly correlated free electrons for applications including quantum information and ultrafast imaging.

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Section: Discussionmentioning

confidence: 99%

Strongly correlated multielectron bunches from interaction with quantum light

Kumar,

Lim,

Rivera

et al. 2024

Sci. Adv.

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“…), each electron emits on average |g Q | 2 photons, in a Poissonian distribution, while in the nonlinear regime 2 NL , we should expect a sub-Poissonian distribution, and vacuum Rabi oscillations as a function of |g Q |. 11 In Section S6, we calculate the total coupling efficiency for a general mode family (labeled by = s TM , TE , HE ij ij ij ), for a transition between initial and final transverse electron eigenstates (labeled "i" and "f"), for mth order phase-matching, and for the two types of phase-matching points, as…”

Section: Strong Free-electron−photon Coupling With High Coupling Idea...mentioning

confidence: 93%

“…For a choice of nonlinearity 2κ = 1.5Δ, the electron excites a single cavity mode and is detuned from the rest, as can be seen in the cavity mode population (Figure 5e) and the evolution of the average photon numbers (Figure 5f), displaying a distinct vacuum Rabi oscillation. This is the so-called Jaynes− Cummings regime, 11 where the electron reduces to an effective two-level emitter interacting with a single mode. Another choice, this time of 2κ = Δ, makes sure that following every recoil, the electron is always phase-matched to a neighboring mode.…”

Section: T Is the Coupling C O N S T A N T F O R E A C H M O D E ( S ...mentioning

confidence: 99%

“…2,3,5,6,18−22 Specifically, measurement of free electrons' energy can be used for the heralded generation of quantum light, such as Fock states, 1,4,8,10,23−25 squeezed states 26 and even cat and GKP states. 9 More recently, it was predicted that free electrons could serve as ancillary qubits for quantum computation 15,16 and provide a platform for nonlinear electron dynamics 27,28 and deterministic single-photon nonlinearities 11,29,30 emerging from quantum recoil. 31,32 Owing to the nature of free-electron emitters, the anticipated single photon nonlinearity can span a vast spectral range 33,34 and operate on femtosecond-temporal and subwavelength-spatial resolution, 35−37 allowing new paradigms in quantum optical technologies.…”

Section: Introductionmentioning

confidence: 99%

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

Karnieli,

Roques-Carmes,

Rivera

et al. 2024

ACS Photonics

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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 guided modes. The first mode applies a ponderomotive trap to the free electron, removing the limitations due to electron diffraction. The second mode strongly couples to the guided free electron with an enhanced coupling that is orders of magnitude larger than previous designs. The extended interaction lengths enabled by our scheme allow for strong single-photon nonlinearities mediated by free electrons. We predict novel quantum effects in our system such as deterministic single-photon emission and nonlinear multimode dynamics. Our proposal paves the way toward the realization of heralded macroscopic nonclassical light generation, deterministic single-photon sources, and quantum gates controlled by free-electron–photon interactions.

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“…Several theoretical works have explored the use of free electrons to herald the production of single photons, entangled photons, and other nonclassical light states, − while a recent experiment has demonstrated Fock photon-state generation in optical resonators correlated with energy losses of the electron . A large electron–photon coupling is then required at the single-electron/single-photon level, which is currently achieved in such resonators by matching the phases of the electron excitation current and the light propagating inside a curved waveguide over an interaction distance of several microns .…”

mentioning

confidence: 99%

Toward Optimum Coupling between Free Electrons and Confined Optical Modes

Di Giulio,

Akerboom,

Polman

et al. 2024

ACS Nano

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Free electrons are excellent tools to probe and manipulate nanoscale optical fields with emerging applications in ultrafast spectromicroscopy and quantum metrology. However, advances in this field are hindered by the small probability associated with the excitation of single optical modes by individual free electrons. Here, we theoretically investigate the scaling properties of the electron-driven excitation probability for a wide variety of optical modes including plasmons in metallic nanostructures and Mie resonances in dielectric cavities, spanning a broad spectral range that extends from the ultraviolet to the infrared region. The highest probabilities for the direct generation of three-dimensionally confined modes are observed at low electron and mode energies in small structures, with order-unity (∼100%) coupling demanding the use of <100 eV electrons interacting with eV polaritons confined down to tens of nanometers in space. Electronic transitions in artificial atoms also emerge as practical systems to realize strong coupling to few-eV free electrons. In contrast, conventional dielectric cavities reach a maximum probability in the few-percent range. In addition, we show that waveguide modes can be generated with higher-than-unity efficiency by phase-matched interaction with grazing electrons, suggesting a practical method to create multiple excitations of a localized optical mode by an individual electron through funneling the so-generated propagating photons into a confining cavityan alternative approach to direct electron–cavity interaction. Our work provides a roadmap to optimize electron–photon coupling with potential applications in electron spectromicroscopy as well as nonlinear and quantum optics at the nanoscale.

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Jaynes-Cummings interaction between low-energy free electrons and cavity photons

Cited by 7 publications

References 88 publications

Strongly correlated multielectron bunches from interaction with quantum light

Strongly correlated multielectron bunches from interaction with quantum light

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

Toward Optimum Coupling between Free Electrons and Confined Optical Modes

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