■ 삼성전자에서주최하는 <제26회 휴먼테크논문대상> 에서 이지현, 백상열, 송진호, 최자윤 학생은 “An Adhesive Patch with Diving Beetle-Inspired Hybrid Suction-Cups for Biofluid Capture and Analysis.” 이라는 연구 결과로 Bio Engineering & Life Science 분과에서 장려상에 입상하였다.
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CHANG HYUN PANG RESEARCH GROUP
Welcome to SP3 Lab
Super-intelligent Polymer 3D-Architecture (SP3) Lab
for Bioinspired Soft Electronics, Robotics and Biomedical Devices
Super-지능형 고분자 3D 아키텍처 연구실
for 생체모사 소프트 전자소자, 로봇, 바이오메디컬 소자
OVERVIEW
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Our vision revolves around several platforms for super-intelligent polymer 3D-architectures with a nature/bio-inspired approach by combining with multi-functional materials and large-area processing.
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Super-intelligent polymer 3D-architectures include hierarchical nano/micro patterning via unconventonal lithography, 2/3/4D-printing, nanostructural assembly, and molecular level chemical treatments.
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Diverse super-intelligent programmable polymer 3D-architectures are investigated through understanding detailed physical and chemical phenomena and finite element analysis simulations.
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By tailoring ultra-intelligent polymer 3D architectures, we are focusing on developing highly efficient deformable electronics, physical/chemical sensors, and soft robots/actuators, metaverse haptic device interfaces, energy harvesting devices, and biomedical drug delivery devices.
Super-intelligent polymer 3D-architectures with bio-inspired for Bioinspired Soft Electronics and Biomedical Devices
ENERGY HARVESTING MATERIALS & DEVICES
E-COMPOSITE MATERIALS for SMART TEXTRONICS
NOTICE
[Post-doc Opening & 대학원생 모집]
지능형 소재 및 인터페이스 연구실에서는 세계적인 연구를 함께 주도할
박사후 연구원 및 대학원생(등록금 전액, 생활비 지원, 해외학회 및 연수 지원)을 모집합니다.
연구분야: 지능형 반도체 전자 소재, 바이오 소재 및 소자, 메타버스 센서 및 부착 소재, 소프트 로봇 소재
LATEST NEWS
Triboelectric Energy: A Micropillar‐Assisted Versatile Strategy for Highly Sensitive and Efficient Triboelectric Energy Generation under In‐Plane Stimuli (Adv. Mater. 2/2020)
Changhyun Pang, Sung Beom Cho, and Sungwoo Chun report a novel and general method for efficient triboelectric energy generation, by assembling artificial micropillars on typical triboelectric nanogenerator devices. The hairy‐structured devices can efficiently harvest electrical energy from in‐plane stimuli such as contact rubbing pressure or noncontact airflow, which works even for extremely small mechanical variations (<0.2 Pa) efficiently.
Sungwoo Chun, Changhyun Pang*, Sung Beom Cho*
See the article: https://onlinelibrary.wiley.com/doi/10.1002/adma.202070009
Spray Coating Technologies: Conductive Hierarchical Hairy Fibers for Highly Sensitive, Stretchable, and Water‐Resistant Multimodal Gesture‐Distinguishable Sensor, VR Applications (Adv. Funct. Mater. 50/2019)
Changhyun Pang, and co‐workers develop conductive hierarchical hairy fibers for a highly sensitive, stretchable, and water‐resistant multimodal gesture‐distinguishable sensor. With multimodal resistance and three‐dimensional microhairy structures on the conductive fiber, the sensor detects three distinct stimuli from the human body. Due to high sensitivity and distinguishability, the presented device is anticipated to be useful for virtual reality applications.
Seunghoon Choi, Kukro Yoon, Sanggeun Lee, Heon Joon Lee, Jaehong Lee, Da Wan Kim, Min‐Seok Kim, Taeyoon Lee, Changhyun Pang*
See the article: https://onlinelibrary.wiley.com/doi/10.1002/adfm.201970344
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