상세 보기
- Sreevanya, Gali Venkatesulu;
- Kim, Kyeong-Bin;
- Jang, Jong-Hyun;
- Lim, Doha;
- Lee, Eun-Ho;
- ... Kim, Han-Ki
WEB OF SCIENCE
2SCOPUS
2초록
Wearable strain sensors are increasingly sought after for applications in human-motion monitoring due to their stretchability, durability, broad strain range, and high sensitivity. This study introduces a novel, bio-inspired strain sensor featuring a DNA-shaped pattern formed through the Kirigami technique to enhance mechanical stretchability. Finite element (FE) simulations were employed to optimize the DNA-based geometry, utilizing the rule of mixtures (ROM) to assess effective material properties. The sensor was fabricated using AgPdCu (APC) and polytetrafluoroethylene (PTFE) hybrid electrodes on a stretchable polyurethane (PU) substrate, enabling accurate detection of both tensile and compressive strains. The resulting device exhibited key performance attributes including high stretchability, low relative resistance change (∼10 %), high sensitivity (gauge factor of 26.75 at 50 % strain), rapid response/recovery time (∼1 s), excellent stability over 10,000 cycles, wide operational range, minimal hysteresis, and high electrical conductivity (3.73 ×104 S cm−1). When applied to human skin, the sensor reliably monitored electrical signals and various body motions, underscoring its strong potential for wearable electronics in applications such as electronic skin and real-time human-motion tracking. © 2025
키워드
- 제목
- Bio-inspired single-step DNA-patterned APC-PTFE hybrid resistive strain sensor with high stretchability and stability for wearable electronics
- 저자
- Sreevanya, Gali Venkatesulu; Kim, Kyeong-Bin; Jang, Jong-Hyun; Lim, Doha; Lee, Eun-Ho; Kim, Han-Ki
- 발행일
- 2025-07-20
- 유형
- Article
- 권
- 1036