Positions
<p>Employ state-of-the-art single-molecule fluorescence methods to study the dynamics of large protein machines. Decipher the role of microsecond-time-scale motions on the function of these machines. </p>

<p>Experience in single-molecule s
<p>Studies of transition times in quantum and classical mechanics. We want to answer the question how long does it take to make a quantum transition. We are also interested in classical transition times for protein folding and the information they give. F
<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>Employ state-of-the-art single-molecule fluorescence methods to study the dynamics of large protein machines. Decipher the role of microsecond-time-scale motions on the function of these machines. </p>

<p>Acquire a broad set of skills,
<p>Developing new neuroimaging methods for studying brain physiology in humans and understanding neurological diseases.</p>
<p>You will be designing & building micro-reactors for in-situ electron microscopy measurements under electrochemical reaction conditions. In collaboration with the EM-Unit, you will be performing experiments with these micro-reactors, optimizing the
<p>Nanoplasmonics- interaction of light with small metallic particles and molecules</p>
<p>Single-molecule fluorescence experiments to study protein folding and dynamics.</p>
<p>Developing new methods for imaging the human brain and understanding neurological diseases.</p>
<p>Developing new neuroimaging methods for studying brain physiology in humans and understanding neurological diseases.</p>
