54 Induced Trapping”. ACS Nano, 2023. • Marc Höll, Alon Nissan, Brian Berkowitz, Eli Barkai. “Controls that expedite firstpassage times in disordered systems”. Physical Review E, 2023. • Gadi Afek, Nir Davidson, David A Kessler, Eli Barkai. “Colloquium: Anomalous statistics of laser-cooled atoms in dissipative optical lattices”. American Physical Society, 2023. • Quancheng Liu, David A Kessler, Eli Barkai. “Designing exceptional-point-based graphs yielding topologically guaranteed quantum search”. Physical Review Research, 2023. • Lucianno Defaveri, Eli Barkai, David A Kessler. “Brownian particles in periodic potentials: Coarse-graining versus fine structure”. Physical Review E, 2023. • Ruoyu Yin, Eli Barkai. “Restart expedites quantum walk hitting times”. Physical Review Letters, 2023. • Lucianno Defaveri, Eli Barkai, David A Kessler. “Brownian particles in periodic potentials: Coarse - graining versus fine structure”. Physical Review E, 2023. • Takuma Akimoto, Eli Barkai, Günter Radons. “Infinite ergodic theory for three heterogeneous stochastic models with application to subrecoil laser cooling”. Physical Review E, 2022. • Lior Zarfaty, Eli Barkai, David A Kessler. “Discrete sampling of extreme events modifies their statistics”. Physical Review Letters, 2022. • A Didi, E Barkai. “Measurement-induced quantum walks”. Physical Review E, 2022. • Amin Padash, Erez Aghion, Alexander Schulz, Eli Barkai, Aleksei V Chechkin, Ralf Metzler, Holger Kantz. “Local equilibrium properties of ultraslow diffusion in the Sinai model”. New Journal of Physics, 2022. • Eli Barkai, Günter Radons, Takuma Akimoto. “Gas of sub-recoiled laser cooled atoms described by infinite ergodic theory”. The Journal of Chemical Physics, 2022. • Gianmaria Falasco, Eli Barkai, Marco Baiesi. “Generalized virial equation for nonlinear multiplicative Langevin dynamics: Application to laser-cooled atoms”. Physical Review E, 2022. • Quancheng Liu, Klaus Ziegler, David A Kessler, Eli Barkai. “Driving quantum systems with periodic conditional measurements”. Physical Review Research, 2022. Dr. Ben-Moshe Assaf Department of Chemistry Member of BINA Nano & Advanced Materials Center Nano-Electro Magnetism & Spintronics Center Nano-Photonics Center Research Areas Nano-scale crystallization phenomena Abstract Our group is developing approaches that utilize nano-scale systems for studies of crystallization phenomena and mechanisms that determine the morphologies of crystals. Insight from this research can lead to very useful technological applications, as understanding crystal growth mechanisms will allow us to better control crystalline products of chemical synthesis. This view is inspired by treating nano-crystals as “embryonic” stages of crystal growth. In a sense, every crystal begins its evolution as a nano-crystal. The huge advantage in studies that follow this perspective is in our ability to utilize extremely powerful electron microscopy methods, including a novel technique that allows us to perform high resolution electron microscopy directly in liquid solutions. In this way we can retrieve details of the crystal structure and overall shape at remarkable resolution, during the crystal’s initial formation. These details are often hidden in bulk crystals, unidentifiable by X-ray crystallography, yet critical for understanding of the mechanisms by which crystals grow. Prof. Brodie Chaya The Mina & Everard Goodman Faculty of Life Sciences Member of BINA Nano-Biomedicine Center Research Areas • Studying the role of protein kinase C in the regulation of cellular growth, differentiation and apoptosis • Studying the molecular mechanisms underlying the development of brain tumors: Exploring signal transduction pathways involved in glial cell Studying nanocrystals using advanced electron microscopy. In this specific image crystallographic features are studied using “4D-STEM” (top panel) and the idea of liquid phase electron microscopy is depicted (Below panel). Publications 2023 • Lia Addadi, Neta Varsano, Assaf Ben Moshe. ”On the Helical Crystals of Cholesterol Monohydrate ”. Helvetica chimica acta, 2023.
RkJQdWJsaXNoZXIy NDU2MA==