Atomic, Molecular, Optical Science

AMOS encompasses the research in
atomic, molecular, and optical science
at the Weizmann Institute of Science.

AMOS Research Areas

AMOS is a center for quantum physics with atomic, molecular, and optical systems, at the Weizmann Institute of Science. The center includes 15 research groups and activities ranging across most contemporary topics in AMO physics - from atto-second pulses and intense lasers, through precision spectroscopy of ultracold atoms, molecules or ions, to quantum information and quantum optics. AMOS members hold faculty appointments in both the Physics and Chemistry Faculties at the Weizmann Institute of Science.

A wide range of interests and scientific excellence contribute to making AMOS one of Israel's leading research centers. AMOS scientists publish annually numerous scientific manuscripts in leading journals.

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News

  • December 2, 2025

    Optica

    Read More about: Optica
  • January 15, 2025

    2024 Tenne Family Prize

  • June 16, 2024

    Morris L. Levinson Prize in Physics

All News

Seminars

  • 02
    Jun 2026
    13:15

    AMOS Journal Club

    Hadar Kaslasi
    Idan Hochner

     

    Photon correlations as a probe of photosynthetic light-harvesting complexes (Hadar Kaslasi)

    In photosynthetic organisms, light-harvesting pigment-protein complexes capture sunlight and transfer excitation energy with remarkable efficiency. Conventional methods probe their dynamics through classical emission properties - intensity, spectra and lifetime. However, treating emitted photons as quantum objects and measuring their correlations provides access to fundamentally different information: the nature of the emitting state, whether a multi-pigment complex behaves as a single emitter, and how emitted photon statistics are affected by excitation source properties.
    In this talk, recent applications of these techniques to photosynthesis, focusing on two ensemble studies, will be presented. Using a heralded single-photon source, Li et al. (Nature 2023)1 provide experimental support in LH2 complexes from purple bacteria to a long-standing assumption - that photosynthesis can be initiated by a single photon. In a follow-up study (Sci. Adv. 2025)2, the same setup was used to compare single-photon and pseudothermal excitation, finding that while fluorescence lifetime and quantum efficiency are unchanged, the photon statistics of the emitted light preserve those of the excitation.
    1.    Li, Q. et al. Single-photon absorption and emission from a natural photosynthetic complex. Nature 619, 300–304 (2023).
    2.    Li, Q., Ko, L., Whaley, K. B. & Fleming, G. R. Comparing photosynthetic light harvesting of single photons and pseudothermal light under ultraweak illumination. Sci. Adv. 11, eadz2616.

     

    Trapping and Cooling of Single Nitrogen Molecular Ions (Idan Hochner)

    Molecules offer a rich quantum structure, with rotational, vibrational, electronic, and isomeric degrees of freedom that are absent in atomic systems. Diatomic homonuclear molecular ions, such as N2+, combine this rich internal structure with comparatively simple spectra and long-lived states, making them promising platforms for precision molecular physics.
    Many of the techniques required to probe and control such systems—state preparation, coherent manipulation, precision spectroscopy, and motional ground-state cooling—are well established in atomic and atomic-ion experiments, where they underpin advances in metrology and quantum information science. Extending these methods to molecules would open new opportunities for quantum control of molecular degrees of freedom, but remains experimentally challenging. In particular, molecular ions must be prepared in a well-defined internal state, detected with high fidelity, and cooled to the ground-state of their external motion.

    I will present our experimental setup for quantum control of single molecular ions. Our approach focuses on preparing individual N2+ ions in the electronic and rovibrational ground state, trapping them alongside atomic ions, and cooling their motion to the quantum ground state. I will describe our progress toward these goals and discuss a planned detection method based on a state-dependent optical dipole force, which provides a route to nondestructive internal-state readout.

    I. Hochner,1 T. Shahaf,1 D. Einav,1 O. Barnea,1 E. Kipiatkov, and Z. Meir1
    1Weizmann Institute of Science, Rehovot, Israel
     

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Publications

  • Sensing Single-Molecule Magnets with Nitrogen-Vacancy Centers

    Smooha A., Kumar J., Yudilevich D., Rosenberg J. W., Bayer V., Stöhr R., Denisenko A., Bendikov T., Kossoy A., Pinkas I., Tan H., Yan B., Sarkar B., van Slageren J. & Finkler A. (2026) Nano Letters.
    Single-molecule magnets (SMMs) are molecules that can function as nanoscale magnets with potential use as magnetic memory bits. While SMMs can retain magnetization at low temperatures, characterizing them on surfaces and at room temperature remains challenging and requires specialized nanoscale techniques. Here, we use single nitrogen-vacancy (NV) centers in diamond as a highly sensitive, broadband magnetic field sensor to detect the magnetic noise of cobalt-based SMMs deposited on a diamond surface. We measured the NV relaxation and decoherence times at 296 K and at 58 K, observing a significant influence of the SMMs on them. From this, we infer the SMMs magnetic noise spectral density (NSD) and underlying magnetic properties. Moreover, we observe the effect of an applied magnetic field on the SMMs NSD at low temperatures. The method provides nanoscale sensitivity for characterizing SMMs under realistic conditions relevant to their use as surface-bound memory units.

  • Unraveling Size Dependent Bi- and Tri-Exciton Characteristics in CdSe/CdS Core/Shell Quantum Dots via Ensemble Time Gated Heralded Spectroscopy

    Scharf E., Liran R., Levi A., Alon O., Chefetz N., Oron D. & Banin U. (2026) Small.
    Multiexcitons in quantum dots (QDs) manifest many-body interactions under quantum confinement and are significant in numerous optoelectronic and quantum applications. Yet, the strong interactions between multiexcitons leading to rapid non-radiative Auger decay introduce challenges for their characterization. While so far, the measurement techniques rely either on indirect methods or on single particle studies, herein a new method is introduced to study multiexcitons in QD ensembles utilizing spectrally resolved time-gated heralded spectroscopy. With this approach, the biexciton binding energies is extracted in CdSe/CdS QD ensembles of several core/shell sizes, manifesting a transition between attractive to repulsive exciton-exciton interactions. Additionally, for triexcitons, involving occupation of two excitons in the 1s energy levels and one exciton in the 1p energy levels, the open issues of extracting the lifetime, the spectra of the two triexciton pathways and their branching ratio are resolved. The ensemble measurements provide high photon counts and low noise levels, and alongside the time-gated heralded approach, thus enable the observation of multiexciton characteristics that are often obscured in single particle studies. The approach can be further implemented in the characterization of the energies and lifetimes of multiexcitons in other QD systems to enable rapid characterization and understanding.