Personals
Prof. Roy Beck
School of Physics and Astronomy
Office: Shenkar Physics 418
Tel: 8477
Email: roy@post.tau.ac.il
Webpage: www6.tau.ac.il/beck
Our research focus is self-assembled structures within the nervous system, which includes the Myelin sheaths, Myelin basic protein, and neuronal intermediate filaments. In those systems alteration in subunit compositions (proteins and/or lipids) has devastative effects commonly expressed in neurodegenerative diseases. A common denominator between those scientific efforts is non-specific interactions and forces that drive order and disorder. In particular, the proteins involve in those supramolecular complexation have large intrinsically disordered domains that lack secondary structure, thus, behaving as a multifaceted polymer.
We couple theoretical and experimental efforts inspired from soft-condensed matter and polymer physics in order to gain physical insights into those complexes where oder and disorder play a key role. This research holds huge potential both for fundamental understating of biological functionality as well as in future biomimetic applications.
Prof. Yair Shokef
School of Mechanical Engineering
Office: Wolfson Mech. Eng. 334
Tel: 8393
Email: shokef@tau.ac.il
Webpage: shokef.tau.ac.il
Current research in the group covers two main directions in the non-equilibrium statistical mechanics of soft matter systems: 1) Stuck Matter: Geometric frustration, jamming, and slow dynamics in granular matter, colloids, foam, glass-forming liquids and mechanical metamaterials, and 2) Live Matter: Nonlinear elasticity and active fluctuations in biological systems.
Prof. Haim Diamant
School of Chemistry
Office: Ornstein 404A
Tel: 6967
Email: hdiamant@tau.ac.il
Webpage: www.tau.ac.il/~hdiamant
Our group attempts to understand the structure and dynamic response of soft materials and complex fluids using analytical models. Recent projects include instabilities in fluid-supported thin sheets, response of actin networks, dynamics of membrane inclusions, correlations in confined colloid suspensions, and osmotic swelling of vesicles.
​
Prof. Roy Beck
School of Physics and Astronomy
Office: Shenkar Physics 418
Tel: 8477
Email: roy@post.tau.ac.il
Webpage: www6.tau.ac.il/beck
Our research focus is self-assembled structures within the nervous system, which includes the Myelin sheaths, Myelin basic protein, and neuronal intermediate filaments. In those systems alteration in subunit compositions (proteins and/or lipids) has devastative effects commonly expressed in neurodegenerative diseases. A common denominator between those scientific efforts is non-specific interactions and forces that drive order and disorder. In particular, the proteins involve in those supramolecular complexation have large intrinsically disordered domains that lack secondary structure, thus, behaving as a multifaceted polymer.
We couple theoretical and experimental efforts inspired from soft-condensed matter and polymer physics in order to gain physical insights into those complexes where oder and disorder play a key role. This research holds huge potential both for fundamental understating of biological functionality as well as in future biomimetic applications.
Prof. Haim Diamant
School of Chemistry
Office: Ornstein 404A
Tel: 6967
Email: hdiamant@tau.ac.il
Webpage: www.tau.ac.il/~hdiamant
Our group attempts to understand the structure and dynamic response of soft materials and complex fluids using analytical models. Recent projects include instabilities in fluid-supported thin sheets, response of actin networks, dynamics of membrane inclusions, correlations in confined colloid suspensions, and osmotic swelling of vesicles.
​
Prof. Michael Urbakh
School of Chemistry
Office: Ornstein 208
Tel: 8324
Email: urbakh@post.tau.ac.il
Webpage: www.tau.ac.il/~urbakh1
The group of Michael Urbakh focuses on theoretical studies of single molecule mechanical unbinding and unfolding of biological molecules, and on friction and molecular transport in nano systems. A number of significant developments that have emerged from this group include novel mechanisms of unbinding of bio-molecules, direct reconstruction of energy landscape from the force measurements, understanding mechanisms of protein diffusion in membranes, and force-induced manipulation of enzymatic activity. Furthermore, new approaches to the construction of nano-scale engines that move either translationally or rotationally and can perform useful functions have been developed.
Dr. Yasmine Meroz
Dept. of Biochemistry and Molecular Biology
Office:
Tel:
Email: jazz@tauex.tau.ac.il
Webpage: www.merozlab.com
Our research focuses on stochastic processes in complex systems, ranging from protein dynamics and transport processes, to granular media and dynamics of tectonic plates. Particularly, we aim at understanding the role of stochasticity in behavioural responses of organisms to external stimuli, e.g. decision-making, adaptation, learning and collective behavior. We adopt plants as a model system; multicellular organisms stripped of neurophysiology, exhibiting a variety of growth-diriven responses to multiple stimuli. Our lab combines experimental and theoretical efforts, adopting tools from statistical physics and applied math.
Prof. Michael Kozlov
Dept. of Physiology and Pharmacology
Office: Sackler (Medicine) 624
Tel: 7863
Email: michk@post.tau.ac.il
Webpage: medicine.mytau.org/kozlov
We work in the field of Cell Mechano-biology which encompasses mechanics and dynamics of cell membranes and cytoskeleton. To describe and analyze the intracellular mechanical processes we use the tools of soft-matter physics and thermodynamics.
Chemistry
Dr. Roey Amir
School of Chemistry
Core member
Office: Shenkar Chemistry 305
Tel: +972-3-640-8435
Email: amirroey@tau.ac.il
Webpage: http://chemistry.tau.ac.il/roeyamir/
Our group focuses on the design, synthesis and characterization of functional polymers for applications ranging from biomedicine to material science. We are specifically interested in the design and synthesis of complex macromolecular building blocks that can self-assemble into functional nano-scale particles and arrays with controllable shapes, sizes and internal architectures.
Prof. Haim Diamant
School of Chemistry
Core member
Office: Ornstein 404A
Tel: +972-3-640-6967
Email: hdiamant@tau.ac.il
Webpage: www.tau.ac.il/~hdiamant
Our group attempts to understand the structure and dynamic response of soft materials and complex fluids using analytical models. Recent projects include instabilities in fluid-supported thin sheets, response of actin networks, dynamics of membrane inclusions, correlations in confined colloid suspensions, and osmotic swelling of vesicles.
Prof. Yuval Ebenstien
School of Chemistry
Core member
Office: Ornstein 312
Tel: +972-3-640-8901
Email: uv@post.tau.ac.il
Webpage: ebenstein.blogspot.co.il
We are trying to characterize sources of variation between genomes.
We use chemistry, biology, physics and computation to tag, detect and analyze genetic and epigenetic patterns along individual genomic DNA molecules
Dr. Shlomi Reuveni
School of Chemistry
Core member
Tel Aviv University, Tel Aviv 69978, Israel
Email: shlomireuveni@hotmail.com
Web: http://shlomireuveni.weebly.com/
The group of Dr. Reuveni is broadly interested in complex systems that are governed by statistical laws and random events. It conducts research at the interface of Physics, Chemistry, Biology, Probability and Statistics; and aims to cut across traditional disciplinary boundaries in attempt to mathematically describe, explain, predict, and understand natural phenomena.
Dr. Yael Roichman
We are interested in studying the underlying physical processes that govern the mechanics, self-organization, dynamics, and statistics of complex fluids out of thermal equilibrium. Our belief is that by studying in detail many such driven systems we will be able to observe emergent shared characteristics, paving the way for a theoretical description.
We use holographic optical tweezers to manipulate and drive microscopic objects, a variety of optical microscopy techniques to image these objects, and image analysis to study their motion and morphology.
Prof. Michael Urbakh
School of Chemistry
​Core member
Office: Ornstein 208
Tel: +972-3-640-8324
Email: urbakh@post.tau.ac.il
Webpage: www.tau.ac.il/~urbakh1
The group of Michael Urbakh focuses on theoretical studies of single molecule mechanical unbinding and unfolding of biological molecules, and on friction and molecular transport in nano systems. A number of significant developments that have emerged from this group include novel mechanisms of unbinding of bio-molecules, direct reconstruction of energy landscape from the force measurements, understanding mechanisms of protein diffusion in membranes, and force-induced manipulation of enzymatic activity. Furthermore, new approaches to the construction of nano-scale engines that move either translationally or rotationally and can perform useful functions have been developed.
Prof. Gil Markovich
School of Chemistry
Core member
Office: Multidisciplinary 207
Tel: +972-3-640-6985
Email: gilmar@post.tau.ac.il
Webpage: chemistry.tau.ac.il/markovich
Nanoscale chirality, soft-templates for growing inorganic nanostructures, thin molecular films