Low-Power and Tunable-Performance Biomemristor Based on Silk Fibroin

Biomemristors have attracted significant attention because of their potential applications in logic operations, nonvolatile memory, and synaptic emulators, thus leading to the urgent need to improve memristive performance. In this work, a silk fibroin (SF)-based memristor, integrated with both low power and low operating current simultaneously, has been reported. Doping the SF with Ag and an ethanol-based post-treatment promote microcrystal formation in the bulk of the SF. This induces carrier transport along fixed, short paths and results in a low set voltage, low operating current, and high memristive stability. Such performances can greatly reduce power consumption and heat generation, beneficial for the accuracy and durability of memristor devices. The memristive mechanism of SF-based memristors with different Ag contents is the space-charge-limited conduction (SCLC) mechanism. In addition, the nonlinear transmission property of SF-based memristors suggests useful applications in bioelectronics.

Automated summary

A silk fibroin-based memristor with low power and low operating current has been developed through doping with Ag and ethanol-based post-treatment, enhancing stability and transport performance. The space-charge-limited conduction mechanism is observed in SF-based memristors with different Ag contents, showing potential applications in bioelectronics.