TY - JOUR
T1 - Reversible conductivity recovery of highly sensitive flexible devices by water vapor
AU - Wang, Yuting
AU - Su, Yingchun
AU - Wang, Zegao
AU - Zhang, Zhongyang
AU - Han, Xiaojun
AU - Dong, MD
AU - Cui, Lifeng
AU - Chen, Menglin
PY - 2018/12/21
Y1 - 2018/12/21
N2 - With decreasing size of integrated circuits in wearable electronic devices, the circuit is more susceptible to aging or fracture problem, subsequently decreasing the transmission efficiency of electricity. Micro-healing represents a good approach to solve this problem. Herein, we report a water vapor method to repair microfiber-based electrodes by precise positioning and rapid healing at their original fracture sites. To realize this micro-level conducting healing, we utilize a bimaterial composed of polymeric microfibers as healing agents and electrically conductive species on its surface. This composite electrode shows a high-performance conductivity, great transparency, and ultra-flexibility. The transmittance of our electrode could reach up to 88 and 90% with a sheet resistance of 1 and 2.8 Ω sq
−1, respectively, which might be the best performance among Au-based materials as we know. Moreover, after tensile failure, water vapor is introduced to mediate heat transfer for the healing process, and within seconds the network electrode could be healed along with recovering of its resistance. The recovering process could be attributed to the combination of adhesion force and capillary force at this bimaterial interface. Finally, this functional network is fabricated as a wearable pressure/ strain sensing device. It shows excellent stretchability and mechanical durability upon 1000 cycles.
AB - With decreasing size of integrated circuits in wearable electronic devices, the circuit is more susceptible to aging or fracture problem, subsequently decreasing the transmission efficiency of electricity. Micro-healing represents a good approach to solve this problem. Herein, we report a water vapor method to repair microfiber-based electrodes by precise positioning and rapid healing at their original fracture sites. To realize this micro-level conducting healing, we utilize a bimaterial composed of polymeric microfibers as healing agents and electrically conductive species on its surface. This composite electrode shows a high-performance conductivity, great transparency, and ultra-flexibility. The transmittance of our electrode could reach up to 88 and 90% with a sheet resistance of 1 and 2.8 Ω sq
−1, respectively, which might be the best performance among Au-based materials as we know. Moreover, after tensile failure, water vapor is introduced to mediate heat transfer for the healing process, and within seconds the network electrode could be healed along with recovering of its resistance. The recovering process could be attributed to the combination of adhesion force and capillary force at this bimaterial interface. Finally, this functional network is fabricated as a wearable pressure/ strain sensing device. It shows excellent stretchability and mechanical durability upon 1000 cycles.
UR - http://www.scopus.com/inward/record.url?scp=85084661304&partnerID=8YFLogxK
U2 - 10.1038/s41528-018-0043-z
DO - 10.1038/s41528-018-0043-z
M3 - Journal article
VL - 2
JO - npj Flexible Electronics
JF - npj Flexible Electronics
IS - 1
M1 - 31
ER -