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

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Seminars

  • 23
    Jul 2024
    13:15

    High speed spatial light modulators for quantum control

    Dr. Sivan Trajtenberg Mills - Massachusetts Institute of Technology (MIT)

    The ability to control and program light is fundamental to science and technology, shaping a vast array of
    fields from optical communications and microscopy, sensing, and astronomy. For some fields, the slow
    devices commercially available today, known as spatial light modulators, are a core bottleneck for mature
    systems – such as 3D holography, imaging through scattering media, and quantum computing.
    Motivated by quantum control applications, where atomic or solid state atom-like qubits require high
    speed addressing in hundreds of sites, and where photonic quantum computing has been explored using
    spatial modes that require millions of degrees of freedom, I explore the development of high speed spatial
    light modulators: devices that can control many spatial degrees of freedom of light at high speeds. In this
    talk I discuss three different platforms that achieve this, each of which offers new advancements and
    insights: First, a nanophotonic plasmonic modulator with liquid crystals fabricated in a “fabless” bulk
    CMOS process[1] which can potentially democratize nanophotonics research, as well as allow for
    multi-layer structures, scalability and electronic integration. Second, a Lithium Niobite on Silicon
    device[2], where thin film LN with a guided mode resonance is bonded to a commercial CMOS
    backplane, allowing for GHz speed modulation arising from the Pockels effect. Finally, a photonic crystal
    array using specially designed photonic crystal cavities[3], working at ~0.2 GHz. With 64-100 pixels, this
    demonstration is one of the largest scale foundry made devices ever made. The automated ‘holographic
    trimming’ achieved a record picometre precision alignment of the cavity resonance for 81 devices.
    These works pave the way for programmable control of millions of degrees of freedom of light at high
    rates.
     

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  • 24
    Jul 2024
    10:00

    PhD Defense

    Eitan Levine

    Asymmetric Effects in Shock Injection for Laser-Plasma Electron Acceleration

    Abstract: Laser-plasma acceleration (LPA), using plasma waves as a medium for transferring energy from an ultra-intense laser pulse to directional kinetic energy of electrons, is a promising candidate for the next generation of particle accelerators, capable of reaching the same energies at less than 0.1% acceleration length compared to classical RF-cavity based accelerators, thanks to the plasma medium's support of extremely large fields. LPA-based multi-GeV electrons [1] and LPA-based free electron lasers [2] have already been demonstrated, and LPA-based medical accelerators for oncological particle therapy are at the focus of interest of many research groups and commercial companies in academia and industry. However, one drawback of current laser-plasma accelerators is their beam quality, notably affected by the process of trapping and injection of ambient electrons into the in-plasma accelerating structure – a process whose improved understanding and development will unlock many other potential uses for these compact accelerators. In my research, the femtosecond relativistic electron microscopy (FREM) method [3], a technique significantly developed in our lab, has been used to probe the highly nonlinear dynamics of one of the most common injection implementations, razor-blade shock injection [4]. We have discovered that the tilt of the generated shock can induce transverse oscillations in the injected electrons until a part of the accelerated bunch splits out of the accelerating structure and drives its own plasma wave. This phenomenon, never reported before, was investigated and characterized, and our hope is that the insights gained by this research will contribute to the improvement of the injection process, and consequently to the overall quality of LPA-based electron beams, enabling this technology to fulfill the promise it holds for so many fields in our lives.

     

    [1] A. J. Gonsalves et al. Petawatt Laser Guiding and Electron Beam Acceleration to 8 GeV in a Laser-Heated Capillary Discharge Waveguide. Phys. Rev. Lett. 122 084801 (2019).

    [2] Marie Labat et al. Seeded free-electron laser driven by a compact laser plasma accelerator. Nature Photonics 17 150-156 (2023).

    [3] Yang Wan, Sheroy Tata, Omri Seemann, Eitan Y. Levine, Slava Smartsev, Eyal Kroupp, and Victor Malka. Femtosecond electron microscopy of relativistic electron bunches. Light: Science & Applications 12 116 (2023).

    [4] K. Schmid et al. Density-transition based electron injector for laser driven wakefield accelerators. Phys. Rev. ST Accel. Beams 13 091301 (2010).

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Publications

  • The Future of Attosecond Science

    Dudovich N., Fang L., Gaarde M., Keller U., Landsman A., Richter M., Rohringer N. & Young L. (2024) .
    Conferences are incredible opportunities to strengthen the inclusive outlook of our scientific community. The participation of female scientists, postdocs, and graduate students in the ATTO VIII conference was remarkable, with more than 40% of female invited speakers. The Local Organizing Committee seized this opportunity to promote an atmosphere that welcomes all. An entirely female evening panel, with experience across the attosecond science spectrum, was convened to explore the Future of Attosecond Science in the evening session of Wednesday, July 13. Furthermore, a booklet entitled Perspectives in Attosecond Science was compiled by Dr. Shima Gholam-Mirzaei of the University of Ottawa and ATTO co-chairs Luca Argenti and Michael Chini, in collaboration with members of the Local Organizing Committee and others, which included interviews with female scientists at all career levels and which was included in the conference materials. The text has been minimally edited to improve clarity and readability.

  • Universal approach for quantum interfaces with atomic arrays

    Solomons Y., Ben-Maimon R. & Shahmoon E. (2024) PRX Quantum.
    We develop a general approach for the characterization of atom-array platforms as light-matter interfaces, focusing on their application in quantum memory and photonic entanglement generation. Our approach is based on the mapping of atom-array problems to a generic 1D model of light interacting with a collective dipole. We find that the efficiency of light-matter coupling, which in turn determines those of quantum memory and entanglement, is given by the on-resonance reflectivity of the 1D scattering problem, r0=C/(1+C), where C is a cooperativity parameter of the model. For 2D and 3D atomic arrays in free space, we derive the mapping parameter C and hence r0, while accounting for realistic effects such as the finite sizes of the array and illuminating beam and weak disorder in atomic positions. Our analytical results are verified numerically and reveal a key idea: efficiencies of quantum tasks are reduced by our approach to the classical calculation of a reflectivity. This provides a unified framework for the analysis of collective light-matter coupling in various relevant platforms such as optical lattices and tweezer arrays. Generalization to collective systems beyond arrays is discussed.