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<h3> Knight Seminars next week! Both seminars will be in our conference room, E19-623 at 4:30pm. </h3><h3></h3><h3></h3><h3> </h3><h3><h3>Tuesday, April 17<br>
</h3><p><a href="http://www.fas.harvard.edu/%7Ehsdept/bios/galison.html">Peter Galison</a>, Director, Collection of Historical Scientific Instruments, Harvard University. </p><p><span class="Apple-style-span" style="font-weight: normal; font-size: medium; ">Galison is interested in the intersection of philosophical and
historical questions such as these: What, at a given time, convinces
people that an experiment is correct? How do scientific subcultures form
interlanguages of theory and things at their borders?</span></p></h3>
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More broadly, Galison's main work explores the complex interaction
between the three principal subcultures of twentieth century
physics--experimentation, instrumentation, and theory. The volume on
experiment (<em>How Experiments End</em> [1987]) and that on instruments (<em>Image and Logic: A Material
Culture of Microphysics</em> [1997]) are to be followed by the final volume--<em>Theory Machines</em>--that is still under construction. <em>Einstein's Clocks, Poincaré's Maps</em> [2003] begins the study of theory by focusing on the ways in which the theory of relativity
stood at the crossroads of technology, philosophy, and physics. <em>Image & Logic</em> won the Pfizer Award from the History of Science Society in October 1998.<br><h3><font class="Apple-style-span" size="3"><span class="Apple-style-span" style="font-weight: normal;"><br></span></font></h3><h3><h3>Thursday, April 19<br>
</h3><p><a href="http://dmse.mit.edu/faculty/profile/van-vliet">Krystyn Van Vliet</a>, Deparment of Materials Science and Engineering, MIT. </p></h3><h6><h3 style="font-weight: normal; font-size: medium; "><span class="Apple-style-span" style="font-weight: normal; font-size: medium; ">Professor Van Vliet's group studies material chemomechanics: material behavior at the interface of mechanics, chemistry, physics, and biology. She focuses on thermodynamically metastable surfaces and interfaces, in which stress-assisted chemical reaction kinetics are notoriously difficult to analyze via either experiment or simulation. The mechanisms of this coupling in cell-material interactions are incompletely understood, due to both biological complexity and lack of appropriate experimental and computational tools, but are key to design of materials that modulate cell adhesion for drug uptake and differentiation. Her long-term goal is to predict and modulate key functions of biological cells by drawing analogies to the coupled chemical/mechanical behavior of structurally simpler, nonbiological material interfaces and nanocomposites. These integrated experimental and computational efforts include three main thrusts: (1) chemomechanical mapping of nanocomposite surfaces including living cells; (2) mechanics of amorphous and viscoelastic surfaces and nanostructures; and (3) chemical kinetics in mechanically strained, nanoscale material interfaces. Her group has used this interdisciplinary application of mechanical and chemical forces to rapidly map environment-structure-property relations in engineered materials, and to predict the binding kinetics of individual molecules on living cells. These studies have shown that the stiffness of materials to which molecular ligands are tethered can directly affect kinetics of ligand-receptor interactions at cell surfaces.</span> </h3><div><br></div></h6><br><div>
Eric Strattman<br>Administrative Assistant<br>Knight Science Journalism at MIT<br><a href="mailto:ejstratt@mit.edu">ejstratt@mit.edu</a><br>617-452-3513<br><br>
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