Piezoelectric sensors are widely used in wearable devices
to mimic
the functions of human skin. However, it is considerably challenging
to develop soft piezoelectric materials that can exhibit high sensitivity,
stretchability, super elasticity, and suitable modulus. In this study,
a soft skin-like piezoelectric polymer elastomer composed of poly(vinylidene
fluoride) (PVDF) and a novel elastic substrate polyacrylonitrile is
prepared by combining the radical polymerization and freeze-drying
processes. Dipole–dipole interaction results in the phase transition
of PVDF (α phase to β phase), which enhances the electrical
and mechanical performances. Thus, we achieve a high piezoelectric
coefficient (d33max = 63 pC/N), good stretchability
(211.3–259.3%), super compressibility (subjected to 99% compression
strain without cracking), and super elasticity (100% recovery after
extreme compression) simultaneously for the elastomer. The soft composite
elastomer produces excellent electrical signal output (Vocmax = 253 mV) and responds rapidly (15 ms) to stress-induced
polarization effects. In addition, the elastomer-based sensor accurately
detects various physiological signals such as gestures, throat vibrations,
and pulse waves. The developed elastomers exhibit excellent mechanical
properties and high sensitivity, which helps facilitate their application
as artificial electronic skin to sense subtle external pressure in
real time.