1. 20 Aug 2025 Journal Article Physical Review Research

    Adding photonic entanglement to superradiance by using multilevel atoms

    Amir Sivan, Meir Orenstein
    Abstract

    We show here that the photonic states emitted by ensembles of multilevel atoms via a superradiance process exhibit entanglement in the modal (frequency) degree of freedom, making this collective emission process a favorable candidate for a fast, bright, and deterministic source of entangled photons. This entanglement is driven by two mechanisms: (i) selective excitation

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  2. 20 Aug 2025 Preprint arXiv

    Sideband Spectroscopy in the Strong Driving Regime: Volcano Transparency and Sideband Anomaly

    Luka Antonic, Sergey Hazanov, Sergei Masis, Daniel K Podolsky, Eyal Buks
    Abstract

    We study the response of a spin to two crossed magnetic fields: a strong and fast transverse field, and a weak and slow longitudinal field. We characterize the sideband response at the sum and the difference of driving frequencies over a broad range of parameters. In the strong transverse driving regime, the emission spectrum has a characteristic volcano lineshape with

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  3. 18 Aug 2025 Preprint arXiv

    Quantum sensing of electron beams using solid-state spins

    Jakob M Grzesik, Dominic Catanzaro, Charles Roques-Carmes, Eric I Rosenthal, Guido L van de Stolpe, Aviv Karnieli, Giovanni Scuri, Souvik Biswas, Kenneth J Leedle, Dylan S Black, Robert L Byer, Ido Kaminer, R Joel England, Shanhui Fan, Olav Solgaard, Jelena Vuckovic
    Abstract

    Scattering experiments with energetic particles, such as free electrons, have been historically used to reveal the quantum structure of matter. However, realizing coherent interactions between free-electron beams and solid-state quantum systems has remained out of reach, owing to their intrinsically weak coupling. Realizing such coherent control would open up opportunities

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  4. 14 Aug 2025 Preprint arXiv

    Reliable high-accuracy error mitigation for utility-scale quantum circuits

    Dorit Aharonov, Ori Alberton, Itai Arad, Yosi Atia, Eyal Bairey, Matan Ben Dov, Asaf Berkovitch, Zvika Brakerski, Itsik Cohen, Eran Fuchs, Omri Golan, Or Golan, Barak D Gur, Ilya Gurwich, Avieli Haber, Rotem Haber, Dorri Halbertal, Yaron Itkin, Barak A Katzir, Oded Kenneth, Shlomi Kotler, Roei Levi, Eyal Leviatan, Yotam Yona Lifshitz, Adi Ludmer, Shlomi Matityahu, Ron Aharon Melcer, Adiel Reuvan Meyer Berman, Omrie Ovdat, Aviad Panahi, ... show all 39 authors
    Abstract

    Error mitigation is essential for unlocking the full potential of quantum algorithms and accelerating the timeline toward quantum advantage. As quantum hardware progresses to push the boundaries of classical simulation, efficient and robust error mitigation methods are becoming increasingly important for producing accurate and reliable outputs. We introduce QESEM, a

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  5. 11 Aug 2025 Preprint arXiv

    Rabi Oscillations Modulated Noise Squeezing in Active Quantum Dot Ensembles

    Ori Gabai, Amnon Willinger, Igor Khanonkin, Vitalii Sichkovskyi, Johann Peter Reithmaier, Gadi Eisenstein
    Abstract

    Generation of squeezed light is usually implemented in nonlinear \c{hi}(2) or \c{hi}(3) materials. Semiconductor lasers and optical amplifiers (SOAs) also offer non-linearities but they differ from passive elements in that they add amplified spontaneous emission noise (ASE). In a semiconductor laser, squeezing to below the shot noise limit has been demonstrated. An SOA

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  6. 11 Aug 2025 Preprint arXiv

    Steady state properties of periodically driven quantum systems

    Abstract

    Periodic driving is used to steer physical systems to unique stationary states or nonequilibrium steady states (NESS), producing enhanced properties inaccessible to non-driven systems. For open quantum systems, characterizing the NESS is challenging and existing results are generally limited to specific types of driving and the Born-Markov approximation. Here we go

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  7. 10 Aug 2025 Preprint arXiv

    Ion Coulomb crystals: an exotic form of condensed matter

    Daniel K Podolsky
    Giovanna Morigi, John Bollinger, Michael Drewsen, Daniel K Podolsky, Efrat Shimshoni
    Abstract

    Wigner crystals formed by laser-cooled ions in traps are unconventional condensed-matter systems, characterized by interparticle distances of several micrometers and energy scales on the order of $\mu$eV. Their crystalline structure emerges from the interplay between Coulomb repulsion and the external confining potential, which can be readily tuned. Moreover, individual

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  8. 8 Aug 2025 Preprint arXiv

    Supercoherence: Harnessing Long-Range Interactions to Preserve Collective Coherence in Disordered Systems

    Alexey Gorlach, Andrea Pizzi, Klaus Mølmer, Joseph Avron, Mordechai Segev, Ido Kaminer
    Abstract

    Artificial quantum systems with synthetic dimensions enable exploring novel quantum phenomena difficult to create in conventional materials. These synthetic degrees of freedom increase the system's dimensionality without altering its physical structure, accessing higher-dimensional physics in lower-dimensional setups. However, synthetic quantum systems often suffer from

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  9. 7 Aug 2025 Journal Article Journal of Applied Physics

    Ultra-low-energy nitrogen ion interactions with diamond surfaces: Impact of crystal orientation on bonding and thermal stability

    Amaresh Das, Sayantan Maity, Shaul Michaelson, Mohan Kumar Kuntumalla, Alon Hoffman
    Abstract

    This study investigates the influence of crystal orientation on nitrogen incorporation, bonding configurations, and thermal stability in (100)- and (111)-oriented single-crystal diamond (SCD) surfaces implanted with ultra-low-energy N2+ ions (100 and 200 eV; dose: 1 × 1015 ions/cm2). Upon impact, N2+ ions dissociate, and each interacting nitrogen atom receives half the

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  10. 6 Aug 2025 Preprint arXiv

    Cybersecurity of Quantum Key Distribution Implementations

    Ittay Alfassi, Ran Schley, Rotem Liss, Tal Mor
    Abstract

    Practical implementations of Quantum Key Distribution (QKD) often deviate from the theoretical protocols, exposing the implementations to various attacks even when the underlying (ideal) protocol is proven secure. We present new analysis tools and methodologies for quantum cybersecurity, adapting the concepts of vulnerabilities, attack surfaces, and exploits from

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