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Department of Condensed Matter Physics
Israel Bar-Joseph, Head
The department was formed in October 1993 as a result of the reorganization of the physics faculty. Presently the scientific activity of this young department is mainly concentrated around the experimental and theoretical research in quantum solid state but also includes a growing group of theoretical astrophysicists.
The newly established Braun Center for sub micron research is an integral part of the department. It is a modern and well equipped center which allows to conduct experiments on sub micron semiconductor structures as well as normal and high temperature superconductors.
T. Alexander
tal.alexander@weizmann.ac.ilStars very near massive black holes.
The Galactic Center.
Gravitational Lensing.
Active Galactic Nuclei.
I. Bar-Joseph
israel.bar-joseph@weizmann.ac.ilOptical spectroscopy of the two-dimensional electron gas in zero and strong magnetic fields.
Near field spectroscopy of semiconductor heterostructures.
Electron-hole complexes in quantum wells: Dynamics and steady state properties.
A. Finkelstein
alexander.finkelstein@weizmann.ac.ilEffects of the electron-electron interaction in low dimensional and disordered systems.
Metal-insulator transition in 2D conductors.
Magnetic fluctuations in high - Tc superconductors.
Y. Gefen
y.gefen@weizmann.ac.ilQuantum dots: Electron electron interaction and dissipation.
The quantum Hall effect.
Interference and tunneling in quantum mechanics.
Dynamical effects, dissipation and thermodynamics in small quantum systems.
Y. Gefen, Y. Imry
M. Heiblum
moty.heiblum@weizmann.ac.ilFractional charges in mesoscopic structures
M. Heiblum, Yunchul Chung, Oern Zarchin, D. Mahalu, V. Umansky
- Charge and statistics of quasiparticles
- Bunching of quasiparticles
- Dilute quasiparticles and their behavior
- High frequency shot noise measurements
III-V semiconductors & their MBE growth
M. Heiblum, H. Shtrikman, V. Umansky
- High speed devices
- High purity semiconductors
Iinterference and dephasing of electrons
M. Heiblum, M. Avinun, I. Neder, D. Rohrlich, D. Mahalu, H. Shtrikman
- Phase measurements via a double path interferometer
- Controlled dephasing via 'which path' detector
- Interferometers functioning in a high magnetic field
Y. Imry
yoseph.imry@weizmann.ac.ilEffects of interaction on localization and on single-electron resonances. Many-electron effects and phase-shifts. Dephasing of Quantum interference in mesoscopics. Quantum noise and its detection. The effects of quantum fluctuations on superconductivity i
Mesoscopic physics: Spectral correlations, persistent currents, fluctuations, quantum interference effects on transport, including the localized phase.
Y. Imry, Y. Gefen
S. Levit
shimon.levit@weizmann.ac.ilQuantum Hall effect: Integer and fractional; Chern-Simon' mean field theory; tunneling of anyons; edge states and excitations; composite bosons and fermions.
Non perturbative methods in Quantum Chromodynamics; random colormagnetic fields; matrix models with free random variables.
Quantum Chaos (small disordered systems) and Interactions.
Statistics of quasiparticle levels and wave functions in interacting quantum dots. Spin effects. Random matrix theory, supersymmetry and replica methods for the description of such systems.
Controlled decoherence of mesoscopic systems. Coupled dephasor-dephasee pairs.
Controlled decoherence of various quantum phenomena such as tunneling, Fano resonances, Berry phases, quantum pumps, Anderson localization, etc.
M. Milgrom
moti.milgrom@weizmann.ac.ilDeparture from Newtonian dynamics as an explanation of the dark-matter problem in galactic systems.
High energy astrophysics: x-ray sources, gamma-ray sources.
Y. Oreg
yuval.oreg@weizmann.ac.ilThe transmission phase shift through a quantum dot that is coupled to leads and forms a many body state (known as the Kondo resonance) is calculated. This work is related to experimental studies at the Braun Center for Submicron Research at the Weizmann I
A generalization of Hund’s rules to disordered dots.
Several aspects of disorder superconductors and normal metal - superconducting junctions are studied, including the interplay between bosons and fermions in this system.
Luttinger liquids in one-dimensional systems.
Bi-layer systems.
D. Shahar
dan.shahar@weizmann.ac.ilExperiments on materials at ultra low-temperatures.
Fractional and integer quantum Hall effect and related phenomena.
Quantum phase transitions: General transport studies and mesoscopics of the metal-insulator, superconductor-insulator and other transitions.
A. Stern
adiel.stern@weizmann.ac.ilQuantum Hall effect and composite fermion theory. Electronic transport in strong magnetic fields. Non-abelian quantum Hall states.
Low density two dimensional electronic systems.
Double layer electronic systems.
V. Usov
vladimir.usov@weizmann.ac.ilThe theory of nonthermal radiation from compact astronomical objects (pulsars, white dwarfs, gamma-ray bursters etc.).
Physical processes in relativistic electron-positron plasma.
Physical processes at the surface and astrophysical appearance of strange-quark-matter stars.
Physical processes in very strong magnetic fields.
Hydrodynamics and high-energy physics of colliding stellar winds in binary systems.
E. Waxman
eli.waxman@weizmann.ac.ilNon-thermal processes in the inter-galactic medium
Gamma-ray bursts: Origin and underlying physics
Ultra-high energy cosmic-rays
High energy neutrino astrononmy
A. Yacoby
amir.yacoby@weizmann.ac.ilElectrostatic imaging of the quantum Hall effect and the 2D metal-insulator transition.
Transport in quantum wires.
Interference and dephasing of composite Fermions.
E. Zeldov
eli.zeldov@weizmann.ac.ilMgB2 and NbSe2 superconductors.
Magneto-optical imaging.
E. Zeldov, a.bVortex dynamics.
High-temperature superconductors.
Vortex matter phase transitions.
This file was last modified on 03/06/2012 13:42:06
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