There is an increasing demand for strain sensors with high sensitivity and high stretchability for new applications such as robotics or wearable electronics. However, for the available technologies, the sensitivity of the sensors varies widely. These sensors are also highly nonlinear, making reliable measurement challenging. Here we introduce a new family of sensors composed of a laser-engraved carbon nanotube paper embedded in an elastomer. A roll-to-roll pressing of these sensors activates a pre-defined fragmentation process, which results in a well-controlled, fragmented microstructure. Such sensors are reproducible and durable and can attain ultrahigh sensitivity and high stretchability (with a gauge factor of over 4.2 x 10(4) at 150% strain). Moreover, they can attain high linearity from 0% to 15% and from 22% to 150% strain. They are good candidates for stretchable electronic applications that require high sensitivity and linearity at large strains.
展开▼
机译:人们越来越对应变传感器的需求高灵敏度和高拉伸性新的应用程序如机器人或可穿戴电子产品。技术,传感器的灵敏度差别很大。非线性,使得可靠的测量具有挑战性的。激光碳组成的传感器纳米管纸嵌入在一个弹性体。精密卷绕对位紧迫的这些传感器的激活一个预定义的分裂过程,结果在一个控制,支离破碎微观结构。耐用,可以实现超高灵敏度和高延性(一个衡量因素4.2 x 10(4) 150%应变)。实现高线性度从0%到15%和22%菌株的150%。挠性电路需要的应用程序高灵敏度和线性压力。
展开▼
