In-situ grown a zeolitic imidazolate framework for boosting sensitivity of breathable wearable electronics

Abstract

Wearable electronics have emerged as versatile platforms for various biomedical applications. However, developing sensors that are both air-permeable and highly sensitive for long-term, subtle physiological signal monitoring remains a challenge. To overcome this, an innovative in-situ growth method was employed to decorate electrospun polyvinylidene fluoride (PVDF) nanofibers with a zeolitic imidazolate framework (known as ZIF-8). This approach has led to a remarkable 300% increase in sensitivity (5.94 kPa−1) compared to sensors prepared using pure PVDF nanofiber (1.42 kPa−1). This in-situ growth method effectively prevented ZIF-8 agglomeration, contributing to the desired improvement in permittivity (∼1.6), unlike blended ZIF-8/PVDF nanofiber. Furthermore, atomic force microscope and simulations were utilized to demonstrated that the nano-scale structures formed by the uniform growth of ZIF-8 significantly contribute to the enhanced sensitivity of the sensor. In addition to satisfactory air-permeability (10 mm/s) and high sensitivity, the as-prepared sensor exhibits excellent flexibility, enabling it to conform to irregular organ surfaces for real-time monitoring of pulse, respiration, and swallowing. This approach holds great promise for the development of highly sensitive and skin-friendly wearable electronics, offering significant benefits for healthcare advancement.