54 Abstract Our research covers a wide range of theoretical problems. These range from quantum search (related to quantum computing), cold atoms physics (lightmatter interactions), dynamics of single molecules in the cell environment (biophysics) and infinite ergodic theory (statistical mechanics). Contamination spreading in strongly disordered systems is described by advection, diffusion as well as symmetry breaking which reveals new effects Publications 2021 and 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. • Zachary Fox, Eli Barkai, Diego Krapf. “Aging power spectrum of membrane protein transport and other subordinated random walks”. Nature communications 12 (1), 1-9, 2021. • Klaus Ziegler, Eli Barkai, David A Kessler. “Randomly repeated measurements on quantum systems: Correlations and topological invariants of the quantum evolution”. Journal of Physics A: Mathematical and Theoretical, 2021. • Felix Thiel, Itay Mualem, David Kessler, Eli Barkai. “Uncertainty relation between detection probability and energy fluctuations”. Entropy, 2021. • Lior Zarfaty, Eli Barkai, David A Kessler. “Accurately approximating extreme value statistics”. Journal of Physics A: Mathematical and Theoretical, 2021. • David A Kessler, Eli Barkai, Klaus Ziegler. “First-detection time of a quantum state under random probing”. Physical Review A, 2021. • Celia Anteneodo, Lucianno Defaveri, Eli Barkai, David A Kessler. “NonNormalizable Quasi-Equilibrium Solution of the Fokker–Planck Equation for Nonconfining Fields”. Entropy, 2021. • M Hidalgo-Soria, Eli Barkai, Stanislav Burov. “Cusp of non-Gaussian density of particles for a diffusing diffusivity model”. Entropy, 2021. Prof. Berkovits Richard Department of Physics Member of BINA Magnetism Center Research Areas • Quantum and statistical mechanics in meso- and nanosystems. • Physical properties of quantum dots and nanoparticle (0D), quantum wires (1D) and quantum well (2D). • Coulomb blockade and magnetization of restricted geometries. • Interaction and disorder effects in nano and mesoscopic systems: persistent currents, quantum chaos, Kondo and im • Quantum phase transitions in low dimensions, many-particle localization, entanglement and networks. • Abstract Quantum and statistical mechanics in meso- and nanosystems. Extracting many-particle entanglement entropy from observables using supervised machine learning Publications 2021 and 2022 • Richard Berkovits. “Large-scale behavior of energy spectra of the quantum random antiferromagnetic Ising chain with mixed transverse and longitudinal fields”. Physical Review B, 2021. • Richard Berkovits. “Probing the metallic energy spectrum beyond the Thouless energy scale using singular value decomposition”. Physical Review B, 2021. Prof. Brodie Chaya The Mina & Everard Goodman Faculty of Life Sciences Dept. of Neurosurgery, Henry Ford Hospital Member of BINA Medicine 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 transformation and identification of novel proteins and genes expressed in brain tumors; development of in vivo and in vitro models of brain tumors; development of novel diagnostic and therapeutic approaches for brain tumors;
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