aizenberglab.seas.harvard.edu
Aizenberg
http://aizenberglab.seas.harvard.edu/index.php?show=research
Skip to main content. Biomineralization and Biomimetics Lab. The level of control that organisms exercise over the materials properties of structural inorganic biomaterials is unparalleled. Dynamic structures that respond reversibly to changes in their environment. The need to fend off water is as fundamental as the need to acquire it: water absorption by buildings fosters mold growth . Micropillar arrays used to emulate diffraction found in the butterfly P. Luna. Cambridge, MA 02138.
aizenberglab.seas.harvard.edu
Aizenberg
http://aizenberglab.seas.harvard.edu/index.php
Skip to main content. Biomineralization and Biomimetics Lab. The level of control that organisms exercise over the materials properties of structural inorganic biomaterials is unparalleled. Dynamic structures that respond reversibly to changes in their environment. The need to fend off water is as fundamental as the need to acquire it: water absorption by buildings fosters mold growth . Micropillar arrays used to emulate diffraction found in the butterfly P. Luna. Cambridge, MA 02138.
seas.harvard.edu
Eliminating entanglements | Harvard John A. Paulson School of Engineering and Applied Sciences
https://www.seas.harvard.edu/news/2015/08/eliminating-entanglements
Skip to main content. Office of the Dean. Learn how your gift supports innovative teaching and cutting-edge research at SEAS. A new strategy towards ultra-soft yet dry rubber. August 10, 2015. Ultra-soft elastomer fabricated by crosslinking bottlebrush polymers contains only crosslinks (red chains) and no entanglements. (Image courtesy of Li-Heng Cai). Now, led by David A. Weitz. Mallinckrodt Professor of Physics and Applied Physics at Harvard John A. Paulson School of Engineering and Applied Sciences.