AIRS in the AIR
AIRS in the AIR | 用于生物医学的独立可拉伸设备平台
可拉伸的电子设备在基础生物医学研究、疾病诊断确认、健康老龄化、人机界面和智能物联网等领域都具有巨大的应用潜力。下一代可拉伸电子设备的实际应用取决于可拉伸持续电源与高灵敏度皮肤传感器和无线传输模块的集成。本期AIRS in the AIR邀请程寰宇副教授介绍独立可拉伸设备平台背后的挑战,设计策略和新颖的制造工艺。
程寰宇是宾夕法尼亚州立大学副教授,他合著发表140多篇论文,总引用次数达18000次,曾获洪堡资深研究人员奖学金、MIT技术评论35岁以下创新者(TR35 China)、福布斯30 Under 30等荣誉。他的团队主要研究独立可伸缩设备平台的设计、制造和应用。
通过Bilibili(http://live.bilibili.com/22587709)参与。
呼吸新鲜空气,了解前沿科技!AIRS in the AIR 为 AIRS 重磅推出的系列活动,与您一起探索人工智能与机器人领域的前沿技术、产业应用、发展趋势。
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朱建AIRS 项目负责人、香港中文大学(深圳)副教授执行主席 -
程寰宇宾夕法尼亚州立大学副教授Standalone stretchable device platform for biomedicineProf. Huanyu "Larry" Cheng is the James L. Henderson, Jr.Memorial Associate Professor of Engineering Science and Mechanics at Penn State University. His research group focuses on the design, fabrication, and application of the standalone stretchable device platform. Larry has co-authored more than 140 publications with total citations >18,000 according to Google Scholar. His work has been recognized through the reception of numerous awards, including the 2023 Emerging Investigator for Nanoscale, Humboldt Research Fellowship for Experienced Researchers, 2022 Minerals, Metals & Materials Society (TMS)Functional Materials Division (FMD) Young Leaders Professional Development Award, 2021 NIH Trailblazer Award, MIT Technology Review Innovators Under 35 (TR35 China) in 2021, 2021 Scialog Fellow in Advancing BioImaging, 2021 Frontiers of Materials Award from TMS, Forbes 30 Under 30 in 2017, among others. He also serves as the associate editor for 7 journals and reviewer for > 250 journals.
Conventional electronics today form on the planar surfaces of brittle wafer substrates and are not compatible with 3D deformable surfaces. As a result, stretchable electronic devices have been developed for continuous health monitoring. Practical applications of the next-generation stretchable electronics hinge on the integration of stretchable sustained power supplies with highly sensitive on-skin sensors and wireless transmission modules. This talk presents the challenges, design strategies, and novel fabrication processes behind a potential standalone stretchable device platform that (a) integrates with 3D curvilinear dynamically changing surfaces, and (b) dissolves completely after its effective operation. The resulting device platform creates application opportunities in fundamental biomedical research, disease diagnostic confirmation, healthy aging, human-machine interface, and smart Internet of Things.
