• Picture of Prof. Igor Lubomirsky

    Prof. Igor Lubomirsky

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    Ice Nucleation on Charged Surfaces (Electrofreezing)
    Collaboration with:  Prof. Meir Lahav
    Ice nucleation
    design of polar crystals and surfaces by symmetry reduction
    non-classical crystal growth
    surface and bulk pyroelectricity
    Fundamentals of electro-chemo-mechanical effects
    local symmetry reduction
    non-classical electrostriction
    ionic conductivity
    elastic interactions in solids with a large concentration of point defects

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  • Picture of Dr. Nir London

    Dr. Nir London

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    Discovery and design of specific covalent inhibitors
    Covalent personalized medicine for cancer
    Computational ligand/drug discovery

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  • Picture of Dr. Yoav Livneh

    Dr. Yoav Livneh

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    Interoception - perception of internal bodily signals
    Cortical computations for modulation of bodily physiology
    Continuous updating in the brain-body loop

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  • Prof. Yaron Lipman

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    Geometric modeling, geometry processing, shape analysis, computer graphics, Discrete differential geometry
  • Picture of Prof. Koby Levy

    Prof. Koby Levy

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    Dynamics, entropy and diffusion in biomoelcular systems
    The mechanisms of protein-DNA recognition: understanding the driving forces for fast assembly

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  • Dr. Emmanuel Levy

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    Design of protein-based super assemblies
    Collaboration with:  Jonathan Doye (Oxford) Samuel Safran (WIS)
    New methods to detect and measure protein interactions
    Computational analyses of protein structure
  • Picture of Prof. Gil Levkowitz

    Prof. Gil Levkowitz

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    hypothalamus
    Developmental neurobiology
    Molecular neurophysiology
    Genetics
    Neuroendocrinology

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  • Picture of Prof. Shimon Levit

    Prof. Shimon Levit

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    Full vector path integrals for light propagation in dielectrics.
    Interaction of Squeezed Light with Atoms and Semiconductor Nanostructures
    Non classical light.
    Resonant scattaring off photonic slabs

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  • Picture of Prof. Sima Lev

    Prof. Sima Lev

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    Breast cancer progression and metastasis.
    Signal transduction therapy for triple negative breast cancer (TNBC).
    PYK2 and FAK as potential therapeutic targets for breast cancer metastasis.
    Chemotherapy resistance and recurrence of breast cancer.

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  • Picture of Dr. Michal Leskes

    Dr. Michal Leskes

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    Our research is focused on correlating structure and function in energy storage and conversion materials by advanced magnetic resonance methods. We aim to understand how the composition of materials affects their functionality and how we can control their functionality through deviation from ideal stoichiometry. In particular we are interested in materials for energy storage, such as Li and Na ion batteries, and in the role interfacial chemistry plays in the functionality of electrode and electrolyte materials. We use a wide range of magnetic resonance techniques: solid state NMR, Electron Paramagnetic Resonance (EPR) and Dynamic Nuclear Polarization (DNP). Additionally we investigate the process of polarization transfer from electron spins to nuclear spins in solids DNP utilizing external and internal polarization agents. For more detailed information, please click below and see our home page.

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