Positions
<p>Designing and building electrochemical and thermal micro-reactor cells for in situ XPS measurements. Reactor cells will be designed both in static mode or in flow mode, using a an x-ray and electron-transparent membrane windows. Reactions of interest i
<p>Positions are for development of lower bounds to energies which compete with the Ritz variational method in accuracy. They are for one year with option of renewal for another year. For more information visit my website: http://www.weizmann.ac.il/chemph
<p>PhD position in designing new methods with UHV-AFM that can provide chemical sensitivity from surfaces. The method relies on distinguishing vdW and electrostatic forces, as well retarded non non-retarded regimes in vdW interactions. <br />
Experie
<p>Designing & building micro-reactors for in-situ electron microscopy measurement under electrochemical reaction conditions. In collaboration with the EM-Unit, performing experiments with these micro-reactors, optimizing the process, and revealing in
<p>Hybrid quantum devices - combining NV centers in diamond with superconducting resonators via mechanical oscillators</p>
<p>Developing new neuroimaging methods for studying brain physiology in humans</p>
<p>Designing & building micro-reactors for in-situ electron microscopy measurement under electrochemical reaction conditions. In collaboration with the EM-Unit, performing experiments with these micro-reactors, optimizing the process, and revealing in
<p>Developing new neuroimaging methods for studying brain physiology in humans</p>
<p>Participating in our experiments on surface-sensitive microscopy and spectroscopy techniques to monitor the processes at the solid-gas interface. </p>
<p>Encapsulated cell on diamond</p>
Studying electronic and spin properties of organic-inorganic interfaces
<p>Development of new methods in multidimensional magnetic resonance (NMR and MRI)</p>
AFM functionality in a confocal fluorescence microscope
<p>Single-molecule fluorescence experiments to study protein folding and dynamics.</p>
<p>Nanoplasmonics- interaction of light with small metallic particles and molecules</p>
1) Detection and measurement of nano-structures with chip-based optical micro-resonators
2) Interactions between single photons and single atoms using laser-cooled atoms and chip-based micro-resonators
<p>Developing new methods for imaging the brain and understanding neurological diseases.</p>
Experimental research in:
(I) Molecular electronics; (II) Molecules as electro-mechanical systems; (III) Nanoscale heat transport; (IV) Sustainable energy and heat to electricity conversion; and (V) Spin transport at the molecular scale.
Magnetic resonance spectroscopy (MRS) and imaging (MRI) of the human brain
