Skin‐like Omnidirectional Stretchable Platform with Negative Poisson's Ratio for Wearable Strain–Pressure Simultaneous Sensor

Abstract Conventional elastomeric polymers used as substrates for wearable platforms have large positive Poisson's ratios (≈0.5) that cause a deformation mismatch with human skin that is multidirectionally elongated under bending of joints. This causes practical problems in elastomer‐based wearable devices, such as delamination and detachment, leading to poorly reliable functionality. To overcome this issue, auxetic‐structured mechanical reinforcement with glass fibers is applied to the elastomeric film, resulting in a negative Poisson's ratio (NPR), which is a skin‐like stretchable substrate (SLSS). Several parameters for determining the materials and geometrical dimensions of the auxetic‐structured reinforcing fillers are considered to maximize the NPR. Based on numerical simulation and digital image correlation analysis, the deformation tendencies and strain distribution of the SLSS are investigated and compared with those of the pristine elastomeric substrate. Owing to the strain‐localization characteristics, an independent strain‐pressure sensing system is fabricated using SLSS with a Ag‐based elastomeric ink and a carbon nanotube‐based force‐sensitive resistor. Finally, it is demonstrated that the SLSS‐based sensor platform can be applied as a wearable device to monitor the physical burden on the wrist in real time.