Intrinsically adhesive, highly sensitive and temperature tolerant flexible sensors based on double network organohydrogels

Hydrogel-based flexible sensors are of promising applications in various fields, but fabrication of such sensors with integrated high performances remains a challenge. In this work, flexible sensors (both strain sensors and pressure sensors) with integrated high performances are fabricated utilizing double network (DN) organohydrogels. Because of the unique structure of DN organohydrogels, the flexible sensors exhibit intrinsic adhesion without introducing components that are often used to obtain adhesive hydrogels, such as polydopamine, nucleobases or proteins. In addition, outstanding temperature tolerance (-18 to 80 ?C), high stretchability (>2000%), tensile strength (>300 kPa), self-healing ability (96.5%) and transparency (90%) are also achieved. Resistive-type strain sensors of DN organohydrogels achieve high gauge factor (GF = 2.58), low response time (0.18 s), large sensing range (0?1000%) and reversible sensing ability (>1000 cycles). Sandwich-shaped capacitive-type pressure sensors comprising DN organohydrogel electrodes with reliefs exhibit a high sensitivity of 2.14 kPa-1. Such flexible sensors can be applied in monitoring various human motions and subtle physiological activities and further promoted as wireless sensors on the basis of a Bluetooth protocol.

Automated summary

Flexible sensors with integrated high performances are fabricated utilizing double network (DN) organohydrogels, exhibiting outstanding temperature tolerance, high stretchability, tensile strength, self-healing ability, and transparency. Resistive-type strain sensors of DN organohydrogels achieve high gauge factor, low response time, large sensing range, and reversible sensing ability, while sandwich-shaped capacitive-type pressure sensors exhibit high sensitivity. These sensors can be applied in monitoring various human motions and subtle physiological activities, and further promoted as wireless sensors.