About bbrettmann

Blair Brettmann is a professor in Materials Science and Engineering at Georgia Tech. She received her bachelor's in chemical engineering from the University of Texas at Austin and her masters and PhD in chemical engineering at MIT. She worked for Saint-Gobain in a polymer (plastic) processing research group for two years before starting a postdoc in molecular engineering at the University of Chicago. Her research focuses on polymer physics, molecular engineering, polymer processing and surface and interfacial science.

Creating nanoscale octopus structures from polymer brushes

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Molecular engineering

Very small structures, much smaller than the human eye can see, often fall in the size range of nanometers. By understanding how the molecules that make up these structures interact, we can engineer them to do many special things that cannot be done at a larger scale. One exciting structure is a polymer brush, in which long, chain-like molecules called polymers are tethered at one end to a surface and stick up from the surface like bristles on a hairbrush. Polymer brushes can be used to keep bacteria away, provide an exceptionally smooth surface for items to slide across, or trap other molecules in solution like a hairbrush traps loose hair. In order to engineer polymer brushes that will perform as desired for a given application, we must understand the physics of how the molecular bristles move, and the chemistry of how they interact with their environment.

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Creating nanoscale octopus structures from polymer brushes2018-01-23T14:57:15+00:00

Use a laser pointer to measure the thickness of your hair!

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Light scattering and diffraction

Have you ever wondered how scientists can accurately measure the size of very small objects like molecules, nanoparticles, and parts of cells? Scientists are continually finding new ways to do this, and one powerful tool they use is light scattering. When an incoming beam of light hits an object, the light "scatters," or breaks into separate streams that form different patterns depending on the size of the object. This incoming light might be visible light, like the light we see from the sun, or it might be higher-energy light like X-rays. The light from commercial laser pointers, it turns out, is perfectly suited to measure the size of a human hair!

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Use a laser pointer to measure the thickness of your hair!2018-03-21T12:30:32+00:00