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January 01, 2013
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Date:18MondayFebruary 2013Colloquia
Faculty of Chemistry Colloquium - Prof. Sir Richard Friend FRS
More information Time 11:00 - 12:30Title ORGANIC SEMICONDUCTOR ELECTRONICSLocation Gerhard M.J. Schmidt Lecture HallLecturer PROFESSOR SIR RICHARD FRIEND, FRS
Cavendish Laboratory, Cambridge, UKOrganizer Faculty of ChemistryContact Abstract Show full text abstract about Pi-conjugated organic molecules and polymers now provide a s...» Pi-conjugated organic molecules and polymers now provide a set of well-performing semiconductors that support a wide range of devices, including light-emitting diodes (LEDs) as used in smart-phone displays, field-effect transistors (FETs) and photovoltaic diodes (PVs). These are attractive materials to manufacture, particularly for large-area applications where they be processed by direct printing.
In this talk I will illustrate those aspects of the physics of their electronic properties that distinguish them from inorganic semiconductors, and that have required specific engineering of material and device design. In particular, these materials have low dielectric constants, and the consequently poor screening of Coulomb interactions causes electron-hole excitations (excitons) to be strongly bound. This often gives very high luminescence efficiency, as required for use in LEDs. For PVs, splitting of excitons to form free electrons and holes can be achieved efficiently at heterojunctions formed between materials with different electronegativities, which act as electron ‘donor’ and ‘acceptor’, and PVs now show up to solar cell 10% efficiency.
Strong Coulomb interactions also give rise to large exchange interactions, so that spin triplet excitons lie generally around 0.5 eV below singlet excitons. Triplet excitons can be formed by electron-hole capture both in LEDs and in PVs, and compromise device efficiency. However triplet-triplet fusion to form a singlet exciton can enhance LED efficiency and singlet exciton fission to triplet exciton pairs can be used to enhance PV efficiency, potentially beyond the Shockley-Queisser single junction limit.
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Date:18MondayFebruary 2013Lecture
Confinement Effects on the Jamming Transition in Kinetically-Constrained Models
More information Time 14:15 - 14:15Location Edna and K.B. Weissman Building of Physical SciencesLecturer Yair Shokef
Tel Aviv UniversityOrganizer Department of Physics of Complex SystemsContact Abstract Show full text abstract about Kinetically-constrained models have trivial interactions and...» Kinetically-constrained models have trivial interactions and relatively simple kinetic rules, which generate clusters of mutually-blocked particles, and thus lead to cooperative and slow relaxation; and ultimately to jamming when the typical size of these clusters exceeds the system size. The Kob-Andersen and Fredricksen-Andersen models, for which the kinetic constraint depends only on the number of neighboring occupied sites, have finite-sized blocked clusters at any particle density, and thus jam only in finite-sized systems. In jamming-percolation models, such as the spiral model, the blocked particles form a system-spanning cluster at finite density, and thus exhibit a singular ergodic-nonergodic phase transition in the thermodynamic limit. In this talk, we present our recent investigation of jamming transitions in kinetically-constrained models. We generalize the spiral model to include density, temperature and nonequilibrium driving as separate control parameters, and disentangle the three different relaxation mechanisms responsible for unjamming when varying each of them. We show that dynamic heterogeneity depends on density much more strongly than on temperature and driving. Subsequently, we study the effects of box size and shape on jamming in the Kob-Andersen and Fredrickson-Andersen models. We show how jamming can occur as the system's aspect ratio is changed, and find that the scaling laws for the critical density vs system size depend on the system's shape. -
Date:19TuesdayFebruary 2013Lecture
Post-translational mechanisms in the mammalian circadian clock
More information Time All dayLocation Wolfson Building for Biological ResearchLecturer Prof. Achim Kramer
Charité - Universitätsmedizin Berlin, GermanyOrganizer Department of Biomolecular SciencesContact -
Date:19TuesdayFebruary 2013Lecture
The Theory of Chaos: Yesterday, Today and Tomorrow
More information Time 11:00 - 11:00Location Jacob Ziskind BuildingLecturer Yakov Pesin
The Pennsylvania State UniversityOrganizer Faculty of Mathematics and Computer ScienceContact -
Date:19TuesdayFebruary 2013Lecture
The Theory of Chaos: Yesterday, Today and Tomorrow
More information Time 11:00 - 11:00Location Jacob Ziskind BuildingLecturer Yakov Pesin
The Pennsylvania State UniversityOrganizer Faculty of Mathematics and Computer ScienceContact -
Date:19TuesdayFebruary 2013Lecture
"Singlet oxygen emerges as a common theme in the plant response to multiple stress"
More information Time 11:15 - 11:15Location Ullmann Building of Life SciencesLecturer Dr. Avishai Mor
The Department of Plant Sciences, Prof. Robert Fluhr's lab, The Weizmann Institute of ScienceOrganizer Department of Plant and Environmental SciencesContact -
Date:19TuesdayFebruary 2013Lecture
Student Seminar
More information Time 13:30 - 13:30Location Wolfson Building for Biological ResearchLecturer Eric Shifrut & Liat Stoller
Eric Shifrut is from Nir Friedman's lab Liat Stoller is from Ronen Alon's lab Each will give a 20-minute talkOrganizer Department of Systems ImmunologyContact -
Date:19TuesdayFebruary 2013Lecture
"Putting extracellular matrix pieces into place with a secreted disulfide catalyst"
More information Time 14:00 - 15:00Location Helen and Milton A. Kimmelman BuildingLecturer Dr. Tal Ilani
Department of Structural Biology - WISOrganizer Department of Chemical and Structural BiologyContact -
Date:19TuesdayFebruary 2013Lecture
On equilibrium measures for henon maps at the first bifurcation
More information Time 16:00 - 16:00Location Jacob Ziskind BuildingLecturer Samuel Senti
Federal University of Rio de JaneiroOrganizer Faculty of Mathematics and Computer ScienceContact -
Date:20WednesdayFebruary 2013Lecture
Forum on Mathematical Principles in Biology
More information Time All dayLocation Arthur and Rochelle Belfer Building for Biomedical ResearchLecturer Prof. Rotem Sorek Organizer Department of Molecular Cell BiologyContact -
Date:20WednesdayFebruary 2013Lecture
Water Forum
More information Time 11:00 - 13:00Title Variety of water states in complex systemsLocation Gerhard M.J. Schmidt Lecture HallLecturer Prof. Yuri Feldman
Department of Applied Physics, Hebrew UniversityOrganizer Department of Immunology and Regenerative Biology , Department of Molecular Chemistry and Materials ScienceContact -
Date:20WednesdayFebruary 2013Lecture
Dimension of self-similar sets with overlaps
More information Time 11:00 - 11:00Location The David Lopatie Hall of Graduate StudiesLecturer Mike Hochman
Hebrew University of JerusalemOrganizer Faculty of Mathematics and Computer ScienceContact -
Date:20WednesdayFebruary 2013Lecture
Next Generation Sequencing: technical aspects of library preparation & application
More information Time 13:00 - 13:00Location Arthur and Rochelle Belfer Building for Biomedical ResearchLecturer Dr. Bjoern Textor
NGS Application Specialist, New England Biolabs GmbHOrganizer Department of Systems ImmunologyContact -
Date:20WednesdayFebruary 2013Lecture
TO BE ANNOUNCED
More information Time 14:00 - 14:00Location Max and Lillian Candiotty BuildingLecturer Prof. Forest White
USAOrganizer Department of Immunology and Regenerative BiologyContact -
Date:20WednesdayFebruary 2013Cultural Events
Voices from Heaven
More information Time 20:00 - 20:00Title Lior Elmaliach, David Daor and Rabbi Haim Louk, accompanied by 8 musiciansLocation Michael Sela AuditoriumContact -
Date:21ThursdayFebruary 2013Lecture
Magnetic Resonance Seminar
More information Time 09:30 - 10:30Title Mapping true T2 relaxation values using standard and model-based reconstruction of undersampled Fast Spin-Echo dataLocation Gerhard M.J. Schmidt Lecture HallLecturer Noam Ben-Eliezer, PhD.
Bernard and Irene Schwartz Center for Biomedical Imaging Department of Radiology, New York University Medical CenterOrganizer Department of Chemical and Biological PhysicsContact Abstract Show full text abstract about T2 contrast is one of the most clinically useful tools for n...» T2 contrast is one of the most clinically useful tools for non-invasive diagnosis and prognosis of pathologies. Although T2 assessment is usually done in a visually-qualitative manner, its quantitative characterization holds valuable information for numerous applications, including detection of biochemical and biophysical changes in the musculoskeletal system, diagnosis of prostate and liver cancer, and the study of various disease models. Genuine in vivo T2 quantification, however, is impractical due to the long scan times associated with acquiring full Spin-Echo (SE) data sets, or, for fast multi-echo SE sequences, is severely hampered by field inhomogeneities, non-rectangular slice profiles, diffusion effects, and by a strong inherent bias due to stimulated and indirect echoes. During my talk, I will present a new approach for in vivo mapping of the true T2 values in clinically feasible scan times that is based on Bloch simulation of the experimental pulse-sequence. The technique is assumption free and furthermore provides a general framework which can be used for fitting additional parameters, including, multiple T2 component, B1 B0 field distributions and more. -
Date:21ThursdayFebruary 2013Colloquia
Seeing Electrons in Two Dimensions: Optical Spectroscopy of Graphene
More information Time 11:15 - 12:30Location Edna and K.B. Weissman Building of Physical SciencesLecturer TONY HEINZ
COLUMBIA UNIVERSITYOrganizer Faculty of PhysicsContact Abstract Show full text abstract about Optical spectroscopy provides an excellent means of understa...» Optical spectroscopy provides an excellent means of understanding the distinctive prop-erties of electrons in the two-dimensional system of graphene. Within the simplest picture, one has a (zero-gap) semiconductor with direct transitions between the well-known conical bands. This picture gives rise to a predicted frequency-dependent absorption of  = 2.3%, where  is the fine-structure constant. We will demonstrate that this relation is indeed satisfied in an appropriate spectral range in the near infrared, but that at higher photon energies electron-hole interactions significantly modify this result through the formation of saddle-point excitons. Optical spectroscopy also permits a detailed analysis of how the linear bands of graphene, corresponding to massless Dirac Fermions, are modified to yield massive electrons through interlayer interactions in bilayer and few-layer graphene sheets. The observation of a tunable band gap in bilayer and trilayer graphene will be discussed. We will also present recent results on monolayers of the transition metal dichalcogenide MoS2. Because of the lowered structural symmetry, this material exhibits a significant band gap, as well as distinctive properties associated with the strong spin-orbit effects, such as the possibility of optical generation of valley polarization. -
Date:21ThursdayFebruary 2013Lecture
The Poisson Equation in Image Stitching
More information Time 12:00 - 12:00Location Jacob Ziskind BuildingLecturer Misha Kazhdan
Johns Hopkins UniversityOrganizer Faculty of Mathematics and Computer ScienceContact -
Date:21ThursdayFebruary 2013Cultural Events
Israel Camerata Jerusalem
More information Time 20:30 - 20:30Title Vive Les Vacances!Location Michael Sela AuditoriumContact -
Date:24SundayFebruary 201301FridayMarch 2013Lecture
FRISNO 2013
More information Time All dayOrganizer Faculty of ChemistryContact