Ultrasensitive flexible magnetoelectric sensor

Ever-evolving advances in flexible magnetic sensors are promising to fuel technological developments in the fields of touchless human-machine interaction, implantable medical diagnosis, and magnetoreception for artificial intelligence. However, the realization of highly flexible and extremely sensitive magnetic sensors remains a challenge. Here, we report a cost-effective, flexible, and ultra-sensitive heterostructural magnetoelectric (ME) sensor consisting of piezoelectric Pb(Zr0.52Ti0.48)O-3 (PZT) thick films and Metglas foils. The flexible sensor exhibits a strong ME coefficient of 19.3 V cm(-1) Oe(-1) at low frequencies and 280.5 V cm(-1) Oe(-1) at resonance due to the exceptionally high piezoelectric coefficient d(33) similar to 72 pC N-1 of the constituent PZT thick films. The flexible ME sensor possesses not only ultrahigh sensitivities of 200 nT at low frequencies and 200 pT at resonance but also shows an excellent mechanical endurance. Through 5000 bending cycles (radii of similar to 1 cm), the sensors showed no fatigue-induced performance degradation. This ultrasensitive flexible sensor provides a platform capable of sensing and responding to external magnetic fields and will find applications in soft robotics, wearable healthcare monitoring, and consumer electronics.

Automated summary

The ever-evolving advances in flexible magnetic sensor technology offer hope for the development of touchless human-machine interaction, implantable medical diagnosis, and magnetoreception for artificial intelligence. However, achieving highly flexible and extremely sensitive magnetic sensors remains a challenge. A cost-effective, flexible, and ultra-sensitive heterostructural magnetoelectric sensor has been reported, demonstrating high sensitivity and excellent mechanical endurance.