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关于麻省理工学院Xuanhe Zhao副教授学术报告的通知

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报告人简介

Xuanhe Zhao received his PhD in Mechanical Engineering from Harvard University. In 2010, Dr. Zhao joint the faculty of Department of Mechanical Engineering and Materials Science, Duke University. In 2014, Dr. Zhao and his group movedQQͼƬ20160315140313.jpg to Department of Mechanical Engineering, MIT, where he is now an associate professor. Dr. Zhao’s current research goal is to understand and design soft materials that possess unprecedented properties and functions. Dr. Zhao is a recipient of the NSF CAREER Award, the ONR Young Investigator Award, and the Early Career Researchers Award from AVS Biomaterial Interfaces Division. He held the Hunt Faculty Scholar at Duke and d'Arbeloff Career Development Chair and Robert N. Noyce Career Development Professor at MIT.

 

报告摘要

Soft materials emerging on the interface between engineering and biological systems are challenging our fundamental knowledge, inspiring technological innovations, and enabling impactful applications. For instance, mammalian muscles, tendons and cartilages, albeit containing ~70% water and having a wide range of rigidity (i.e., 100kPa~10MPa), can maintain impressively high fracture toughness (i.e., >1000 Jm-2) under millions of cycles of loads. Marine mussels and barnacles secret soft glues to form robust adhesions (i.e., >100 Jm-2) to rocks and metals in flowing water with high salinity. Camouflage animals such as cephalopods can dynamically vary hierarchical textures and colors of their skins within seconds to blend in diverse environments. 

 

       At MIT SAMs Lab, we integrate theory and experiments to understand the physics and mechanics of these intriguing biological materials and phenomena, and seek bio-inspirations to design new soft materials to achieve extraordinary properties. We propose that judicious designs of unconventional polymer networks such as interpenetrating networks, multimodal chain distributions, hybrid crosslinkings, transformable domains and fiber reinforcements represent a general strategy to achieve soft materials with extraordinary properties. Guided by this strategy and theoretical models, I will demonstrate examples of our recent designs including: (1) a set of new soft materials with similar water contents and moduli as muscles, tendons and cartilages but much higher fracture toughness (i.e., >10,000 Jm-2) and anti-fatigue properties; (2) new underwater soft glues that bond to diverse solids including glass, ceramics, silicon, metals and polymers with interfacial toughness (i.e., >1500 Jm-2) much higher than their natural counterparts; and (3) new active polymers that can change both topographic textures and colors under the control of programed voltages. I will conclude this talk by briefly discussing two emerging manufacturing strategies of soft materials: synthetic biology for new biopolymers and nanostructures, and 3D printing for new microstructures.

 

 

: 319(周六) 下午14:30-15:30

: 浙江大学玉泉校区教5-333


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