Department of Materials and Interfaces
Reshef Tenne, Head
The scientific research of the department focuses on the understanding and design of functional materials with unique physical and chemical properties. This includes a broad range of materials, such as solids with extended bonding displaying cooperative properties (superconductors and semiconductors); nanomaterials, like carbon nanotubes, and inorganic nanotubes; ultra thin ferroelectric films; solids and liquids with mainly molecular bonding, such as complex fluids and molecular crystals; ultra-thin organic, inorganic and biological films and assemblies; size-quantized nanoparticles and fulleroids; molecularly functionalized semiconductors; metals and polymers, including polymer brushes and polymers for cloud seeding; and nanocomposites displaying unique mechanical properties. Biopolymer mechanics and molecular transport phenomena in the cell; imitation of biological transport strategies. Planned self-assembly of novel nanostructures on scanning-probe-patterned organic monolayer templates. Three new research groups have been established over the last few years: Dr. Ernesto Joselvich-carbon nanotubes and scanning probe microscopy; Dr. Roy Bar-Ziv-studies the mechanisms of biological transcription on silicon chip using microfabriction and microfluidics. Dr. Leeor Kronik- uses density functional theory to study clusters; magnetic nanoparticles; nanocrystalline material; inorganic-organic interfaces and optical phenomena in semiconductors. The group of Dr. Igor Lubomirsy studies nanocrystalline electrocermaic films, and quasi amorphous films of ceramic materials, in particular.
Several groups in the department are developing novel theoretical and experimental methodologies for probing liquid-liquid, solid-liquid, solid-solid, solid-gas and liquid-gas interfaces. These include force measurements techniques at Ångstrom surface separation; nanomechanical testing of carbon and inorganic nanotubes; electrochemistry; grazing angle X-ray diffraction and X-ray reflectivity using bright and collimated light from synchrotron sources; optical tweezers; scanning probe microscopy and spectroscopy, grazing angle infrared spectroscopy; and unique applications of X-ray photoelectron spectroscopy. Two new research facilities, which are used extensively by the department scientists, have been completed this year, i.e the high resolution electron microscopy laboratory, and the combined clean rooms/microfabrication/biological specimen manipulation laboratory.
POLY- & NANO-CRYSTALLINE SOLAR CELLS, THEIR CHEMISTRY & PHYSICS
D. Cahen, in cooperation with G. Hodes, S. Cohen, K. Gartsman; A. Zaban (Bar Ilan U)
- Molecular electronics for poly- and nano-crystalline solar cells.
- Nanocrystalline solar cells: how do they work?
- Self-assembling solar cells (with Univ. Uppsala)
- Scanning probe & Electron beam microscopies for nanoscale solar cell characterization
- How can polycrystalline solar cells outperform than their single crystal analogues?
MOLECULE-CONTROLLED ELECTRONICS, OPTOELECTRONICS & BIO-OPTOELECTRONICS
D. Cahen, Cooperations with M. Sheves, M.vanderBoom, A Shanzer, R.Arad-Yellin,; C.Sukenik(Bar Ilan), F.Diederich(ETHZ), A.Kahn,J.Schwartz(Princeton),G.Meyer(John Hopkins)
- Understanding and controlling electrical contacts to molecules
- Molecular electronic sensors, Fundamentals (why?) and practice (how?)
- Unique molecular electronic device effects: Negative Differential Resistance and more
- Towards bio-optoelectronics:Science and practice of Bacteriorhodopsin- based devices
PHOTO-ASSISTED WATER PURIFICATION: Use of mesoporous, nanoparticulate membrane electrodes.
D. Cahen, in cooperation with A. Zaban (Bar Ilan U), A. Abed Rabbo & H. Hallak (Bethlehem U)ELECTRON TRANSPORT ACROSS MOLECULES AND MOLECULAR LAYERS
D. Cahen, in cooperation with L. Kronik, A. Nitzan (Tel Aviv Univ.), R. Naaman
- Fundamental mechanisms for electronic charge transport through molecules
- How can information be transferred across insulating molecular layers?
M. Elbaum
Single-molecule manipulations using optical tweezers.
Dynamics of DNA uptake into the cell nucleus.
Structure and function of the nuclear pore complex (with Z. Reich): application of atomic force microscopy and advanced optical spectroscopies.
Anomalous diffusion in polymer networks and living cells (with R. Granek).
Organization of forces driving cell movements (with A. Bershadsky): optical force measurements and particle tracking studies; influence of cell biochemistry on biophysical forces.
Novel surface-patterning lithographies.
G. Hodes
Electrochemical and chemical bath deposition of nanocrystalline semiconductor quantum dot (QD) films.
Surface modification of semiconductor nanocrystals.
Charge transfer in QDs.
Thin film photovoltaic cells.
G. Hodes, Prof. David Cahen
J. Klein
Experimental studies of surface structure and interactions, and of the behavior of confined simple and polymeric fluids.
Surface-forces-measurement techniques at angstrom surface separations; polymers as molecular lubricants; properties of thin liquid films including aqueous electrolytes and polyelectrolytes.
Nuclear reaction analysis investigations of polymer interfaces. Interfacial structure and phase equilibrium between incompatible polymers; studies of transport and self-diffusion in bulk polymers.
Wetting and stability of thin films; use of polymer surfactants to modify surface and interfacial behaviour.
Spintronic materials: electronic and magnetic properties
Organic semiconductors: structural and electronic properties
L. Kronik, E. Umbach, C. Heske (U. Wurzburg, Germany)Quantum dots: optical properties
Site-specific photoelectron spectroscopy: predicting & explaining experiment
L. Kronik, J. C. Woicik (NIST, USA)Nano-clusters: non-equilibrium effects
molecular electronics
L. Kronik, D. Cahen (WIS), A. Nitzan (Tel Aviv Univ.)
I. Lubomirsky
Properties of Ultra-Thin Self-Supported Crystalline Oxide Films.
Infrared focal plane array based on freestanding pyroelectric films.
Oxygen ion transport in thin freestanding films.
S. Reich
Localized high Tc superconductivity was obtained on Na+ doped surface of WO3 crystals.
Cs+ and Rb+ surface doping is used to induce surface superconductivity in various crystallographic phases of WO3.
Self-assembled supramolecular systems on surfaces.
I. Rubinstein, A. VaskevichNanostructures based on surface-modified nanoparticles.
I. Rubinstein, A. VaskevichCoordination self-assembly of nanostructures comprising organic / inorganic building blocks.
I. Rubinstein, A. Shanzer, A. VaskevichChemical and biological sensing using transmission surface plasmon resonance (T-SPR) spectroscopy.
I. Rubinstein, A. VaskevichNanomaterials prepared by template synthesis in nanoporous membranes.
I. Rubinstein, A. VaskevichStatistical physics of soft matter:
- Membrane self-assembly of surfactants, lipids, and amphiphilic polymers.
- Coupling of shape and shear elasticity in membranes and in biological cells.
- Adhesion of cells to surfaces; elastic interactions of cells
- Membranes: tension induced fusion, inclusions (such as proteins) in membranes.
- Electrostatic and fluctuation induced interactions in charged colloidal and membrane systems.
- Microemulsions: structure, phase behavior, dynamics.
J. Sagiv
Studies on novel types of artificial organic-inorganic hybrid superlattice structures with intercalated metal or semiconductor nanoparticles, including collaborative work on characterization by synchrotron X-ray scattering, scanning probe microscopies and
J. Sagiv, R. MaozSelf-replicating multilayers.
J. Sagiv, R. MaozPlanned surface self-assembly of nanoscopic organic-inorganic architectures using a scanning probe initiated process of non-destructive nanoelectrochemical patterning of stable self-assembled monolayers.
J. Sagiv, R. Maoz, S. CohenInorganic nanotubes and inorganic fullerene-like materials: new materials with cage structure.
Interface micromechanics in composite materials, including characterization by micro-Raman spectroscopy.
Mechanics of single- and multi-wall carbon nanotubes, nanofibers and their composites.
Mechanics of biological composites.
D. Wagner, S. Weiner, L. Addadi