학력
- 2017 한양대 공학박사 (생체공학)
- 2012 부산대 공학사-석사 연계 (나노소재공학)
경력
- 2024.03 – 현재 한양대학교 공과대학 바이오메디컬공학과 부교수
- 2020.03 – 2024.02 동국대학교 공과대학 에너지신소재공학과 조교수
- 2017.08 – 2020.02 DGIST 융합연구원 선임연구원
활동
- 한국전기화학회 국문지편집위원회 학술위원
- 한국전기전자재료학회 국문지편집위원회 학술위원
수상내역
- 우수논문상 (2023, 전기전자재료학회)
- 우수논문 발표상 (2023, 센서학회)
- 우수논문 발표상 (2022, 대한금속 재료학회)
- Best teaching prof. 공학부문 (2021, 동국대학교)
- 19년 기관 최우수 학술상 표창 (2019, DGIST)
- 대통령 포스닥 펠로우십 선정 (2017, 교육부)
- 연구실적 우수자상 (2017, 한양대학교)
- 글로벌 박사 펠로우십 선정 (2014, 한국연구재단)
- 우수발표 논문상 (2011, 한국재료학회)
- 우수발표 논문상 (2010, 한국재료학회)
주요논문
- (교신) μm-thick and water-taping protein electronic tattoos for multifunctional on-skin electronics (2025).
- (교신) Transition of short-term to long-term memory of conductive bridge random access memory on wrinkled CNT substrate for neuromorphic engineering, Carbon (2023).
- (교신) Hierarchically-plied, mechano-electrochemical energy harvesting using a scalable kinematic sensing textile woven from a graphene-coated commercial cotton yarn, Nano Letters (2023).
- (교신) Pore-Controlled Carbon Nanotube Sheet Anodes for Proton/Anion-Exchange Membrane Water Electrolyzers, Chemical Engineering Journal (2023).
- (교신) Micro-buckled mechano-electrochemical harvesting fiber for self-powered strain sensors and energy harvesters, Nano Letters (2022).
- (교신) High-power hydro-actuators fabricated from biomimetic carbon nanotube coiled yarns with fast electrothermal recovery, Nano Letters (2022).
- (교신) Twist-Stabilized, Coiled Carbon Nanotube Yarns with Enhanced Capacitance, ACS Nano (2022).
- (교신) Hierarchically porous, biaxially woven carbon nanotube sheet arrays for next-generation anionexchange membrane water electrolyzers, Journal of Materials Chemistry A (2022).
- (교신) DNA-inspired, highly packed supercoil battery for ultra-high stretchability and capacity, Nano Energy (2021).
- (교신) Extremely flexible and mechanically durable planar supercapacitors: High energy density and low-cost power source for E-skin electronics, Nano Energy (2020).
- (교신) Highly twisted supercoils for superelastic multi-functional fibres, Nature Communications (2019).
- (교신) Self-Powered Pressure- and Vibration-Sensitive Tactile Sensors for Learning Technique-Based Neural Finger Skin, Nano Letters (2019).
교내 매체