77 In a parallel effort, we develop and fabricate fiber devices such as long period fiber gratings, fiber micro-knots, fiber micro-resonators, micro-lasers etc. Synchronization of human networks. Publications 2020 and 2021 • Sara Meir, Eliahu Cohen, Moti Fridman. “Spectral and temporal structure of nonclassical light”. Optical and Quantum Sensing and Precision Metrology 11700, 1170024, 2021. • Avi Klein, Sara Meir, Hamootal Duadi, Arjunan Govindarajan, Moti Fridman. “Polarization dynamics of ultrafast solitons”. Optics Express, 2021. • Hamootal Duadi, Avi Klein, Inbar Sibony, Sara Meir, Moti Fridman. “Cross-phase modulation aberrations in time lenses”. Optics Letters, 2021. • Avi Klein, Inbar Sibony, Sara Meir, Hamootal Duadi, Michelle Y Sander, Moti Fridman. “Temporal imaging with a high filling factor”. APL Photonics, 2020. • Avi Klein, Inbar Sibony, Sara Meir, Ori Freedman, Shir Shahal, Hamootal Duadi, Moti Fridman. “Time-lenses placed in an array with overlapping between adjecent time-lenses”. Nonlinear Optics and its Applications, 2020 11358, 113581N. • Sagie Asraf, Moti Fridman and Zeev Zalevsky. “Fibers-based temporal superresolved imaging.” Sci Rep 10, 17750, 2020. • Avi Klein, Inbar Sibony, Sara Meir, Hamootal Duadi, Michelle Y. Sander, and Moti Fridman. “Temporal imaging with a high filling factor.” APL Photonics 5, 090801, 2020. • Shir Shahal, Ateret Wurzberg, Inbar Sibony, Hamootal Duadi, Elad Shniderman, Daniel Weymouth, Nir Davidson, and Moti Fridman. “Synchronization of complex human networks”. Nat Commun 11, 3854, 2020. • Asaf Olshinka, Dean Ad-El, Elena Didkovski, Ela Kaganovsky, Rinat Ankri, Nitza Goldenberg- Cohen and Dror Fixler. “Diffusion Reflection Measurements of Antibodies Conjugated to Gold Nanoparticles as a Method to Identify Cutaneous Squamous Cell Carcinoma Borders”. Materials 13(2), 447, 2020. Prof. Fridman Moti Faculty of Engineering Member of BINA Nano-Photonics Center Research Areas • Temporal optics Temporal depth imaging Time-lenses for orthogonal polarized input signals Temporal super resolution methods Full Stocks time-lenses Temporal and spatial evolution of ultrafast rogue waves • Fiber Devices Long period fiber gratings Gold coated tapered fibers Fiber micro-knots • Fiber lasers Carbon nanotubes Graphen Topological insulators Abstract Temporal optics Temporal optics is a new and evolving field, and utilizing it can revolutionize optical data processing. Our lab focuses on developing advanced temporal optics devices such as time-lenses, temporal microscope, temporal cavities, etc. We design, fabricate and assemble the main building blocks of the temporal schemes which are the ultra-fast laser and the highly nonlinear fiber. Thanks to these abilities, and together with the experience in complex temporal schemes we are able to pursue advanced temporal schemes which were never been done before. Our temporal devices are useful for basic research of ultra-fast phenomena as well as for the telecommunication industry leading toward full optical data processing. Prof. Frydman Aviad Department of Physics Member of BINA Nano-Magnetism Center Research Areas • Thin film growth: Thermal evaporation, e-beam evaporation UHV techniques and quench- condensation methods. • Advanced Lithography: Electron beam nano-lithography and Photo-lithography, ion milling, reactive ion milling, chemical etching and other processing techniques applicable to sub-micron electronics. • Microscopy: Scanning and transmission electron microscopy, scanning tunneling microscopy (STM) and atomic force microscopy (AFM). • Low Temperature: Cryogenic measurement techniques, low noise measurements, dc and ac (lock-in) techniques, high field magneto-transport measurements. Abstract Electronic properties of low dimensional systems Electrons in solids behave as quantum waves which may interact and interfere. The quantum electronic nature, which becomes important in reduced dimensionality and low temperatures, has a significant influence on properties such as electric conductivity, magneto-transport and density of states. Our lab is interested in the interplay between geometry, dimensionality, disorder and electronic properties of solid state systems. Using advanced nano -fabrication techniques, high precision electric measurements and low temperature techniques we study the properties of different geometries such as ultrathin films, nanowires, granular films and quantum dots focusing on disordered metals, superconductors and ferromagnets. Currently the group’s areas of interest include the disorder induced superconductor- insulator-transition, transport through nanosystems and heterostructures of disordered systems and single layer graphene.
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