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Showing 1–6 of 6 results
Advanced filters: Author: Mark A. Kasevich Clear advanced filters

  • Low-damage and high-precision imaging can be achieved by passing the same probe photons through the specimen more than once, and this has been previously achieved in double-pass transmission microscopy. Here, the authors generalize this idea to full-field multi-pass microscopy using a self-imaging cavity.

    • Thomas Juffmann
    • Brannon B. Klopfer
    • Mark A. Kasevich
    ResearchOpen Access
    Nature Communications
    Volume: 7, P: 1-5

  • A spatially distributed, atomic clock network entangled via quantum nondemolition measurements offers better precision and lower noise compared to an equivalent mode-separable network, and the improvements scale with network size.

    • Benjamin K. Malia
    • Yunfan Wu
    • Mark A. Kasevich
    Research
    Nature
    Volume: 612, P: 661-665

  • A simulation method connects single-shot measurements in ultracold atom experiments to the probability distribution of the many-body wavefunction, elucidating the role of the fluctuations in different experimental situations.

    • Kaspar Sakmann
    • Mark Kasevich
    Research
    Nature Physics
    Volume: 12, P: 451-454

  • Nanosecond imaging techniques, such as fluorescence lifetime imaging microscopy (FLIM), are limited by low efficiency of current detectors. Here, the authors implement an electro-optic approach using Pockels cells for wide-field image gating and demonstrate high throughput FLIM on standard camera sensors.

    • Adam J. Bowman
    • Brannon B. Klopfer
    • Mark A. Kasevich
    ResearchOpen Access
    Nature Communications
    Volume: 10, P: 1-8

  • Quantum entanglement is thought to offer great promise for improving measurement precision; now a spin-squeezing implementation with cold atoms offers levels of sensitivity unavailable with any competing conventional method, sensing microwave induced rotations a factor of 70 beyond the standard quantum limit.

    • Onur Hosten
    • Nils J. Engelsen
    • Mark A. Kasevich
    Research
    Nature
    Volume: 529, P: 505-508