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New, hybrid RoboBee can fly, dive into water, swim, propel itself back out of water, and safely land. The RoboBee is retrofitted with four buoyant and a central gas collection chamber. Once the RoboBee swims to the surface, an electrolytic plate in the chamber converts water into oxyhydrogen, a combustible gas fuel. (Image courtesy of Yufeng Chen/Harvard SEAS) We’ve seen RoboBees that can fly, sti
Harvard researchers have developed a general framework to design reconfigurable metamaterials that is scale independent, meaning it can be applied to everything from meter-scale architectures to reconfigurable nano-scale systems (Image courtesy of Johannes Overvelde/Harvard SEAS). Metamaterials — materials whose function is determined by structure, not composition — have been designed to bend ligh
Soft robotic gripper is attached (lower left) to the remotely operated vehicle (ROV) as it is lowered into the Red Sea for a test dive. (Photo courtesy of Kevin Galloway, Wyss Institute at Harvard University.) Soft Robotic Grippers For Deep-Sea Exploration from Wyss Institute on Vimeo. CAMBRIDGE, Ma. and NEW YORK, N.Y. – Jan. 20, 2016 – During a 2014 talk on his exploration of deep sea coral reefs
A new ultrathin, flat lens focuses light without imparting the optical distortions of conventional lenses. (Artist's rendition courtesy of Francesco Aieta.) Left to right: Francesco Aieta, Federico Capasso, and Patrice Genevet. (Photo by Eliza Grinnell, SEAS Communications.) Cambridge, Mass. – August 23, 2012 – Applied physicists at the Harvard School of Engineering and Applied Sciences (SEAS) hav
Postdoctoral Fellow in Materials Science and Mechanical Engineering
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