Xuanhe Zhao joined the MIT faculty in September 2014 as an assistant professor.
The mission of MIT is to advance knowledge and educate students in science, technology and other areas of scholarship that will best serve the nation and the world in the 21st century. The tape could eventually replace surgical sutures, which don’t work well in all tissues and can cause complications in some patients.Researchers including Professor Xuanhe Zhao, grad student Hyunwoo Yuk, and postdoc Xiaoyu Chen have developed an adhesive could make it easier for surgeons to close up internal wounds.Professor Xuanhe Zhao has 3-D-printed soft electronically active polymers into devices, developing flexible neural implants that can gently conform to the brain’s contours and monitor activity longer.Massachusetts Institute of TechnologyDepartment of Mechanical Engineering77 Massachusetts Avenue, Room 3-173 ... MIT Financial GROUP. 113. Perhaps searching can help. By developing novel theoretical and computational approaches, my research group aims to provide a high-resolution characterization of the three-dimensional genome organization, to unravel the molecular mechanisms that dictate its setup, and to elucidate its impact on regulating gene expression and establishing cell fate. View Marina Zhao’s profile on LinkedIn, the world's largest professional community. GENERAL INQUIRIES. Group alumni. Shanghai University. At MIT, he will work jointly with the Shao-Horn group on the discovery of new electrolyte materials using high-throughput methods. In the application, please indicate your interests in working at Zhao Laboratory. Motivated MIT undergraduate students are encouraged to contact Dr. Xuanhe Zhao (zhaox@mit.edu) for possible UROP positions. GENERAL INQUIRIES. In the application, please indicate your interests in working at Zhao Laboratory. Zhao Lab Massachusetts Institute of Techonology, 77 Massachusetts Avenue Room 1-025 Cambridge, MA 02139-4307. By harnessing surface instabilities such as wrinkles and creases in 2014, he dynamically varied both surface textures and colors of an electro-mechano-chemically responsive elastomers to achieve the dynamic-camouflage function of cephalopods. Massachusetts Institute of TechnologyMIT engineers led by Associate Professor Xuanhe Zhao have designed a double-sided tape that can seal tissues in just five seconds. Phone: 617.253.5328 Email: cspinell@mit.edu. Education. Admitted graduate students in MechE, MSE, CEE, ChemE, and BE are welcome to contact Dr. Xuanhe Zhao (zhaox@mit.edu) to discuss possible PhD/MS projects.Motivated MIT undergraduate students are encouraged to contact Dr. Xuanhe Zhao (zhaox@mit.edu) for possible UROP positions.
His current research projects are centered on three bioinspired themes: artificial muscle (dielectric polymers & electromechanics), tough cartilage (tough and bioactive hydrogels & biomechanics), and transformative skin (functional surface instabilities & thin film mechanics). Before joining MIT, he was an assistant professor in the Department of Mechanical Engineering and Materials Science at Duke University. Telephone: 617-324-6367 Fax: 617-258-8742 Email: zhaox@mit.edu Assistant: Marjorie A. Joss / maj@mit.edu Research Website: https://zhaox.org For a full pdf of Xuanhe Zhao’s Curriculum Vitae
MIT engineers led by Associate Professor Xuanhe Zhao have designed a double-sided tape that can seal tissues in just five seconds. With fiber reinforcements, Xuanhe further controlled the modulus of the tough hydrogel over a wide range from a few kPa to over 10 MPa in 2013 and 2014. Zhao Lab Massachusetts Institute of Techonology, 77 Massachusetts Avenue Room 1-025 Cambridge, MA 02139-4307.
MIT Spotlight. His current research goal is to understand and design new soft materials with unprecedented properties for impactful applications. In 2012, he designed a new synthetic biocompatible hydrogel with hybrid crosslinking, which achieved fracture toughness multiple times higher than articular cartilage — unprecedented by previous synthetic gels. Xuanhe’s discovery of new failure mechanisms of dielectric polymers in 2011 and 2012 can potentially enhance electric energy densities of dielectric elastomers and gels over ten times. MAILING ADDRESS.