Superlubric Nanogenerators with Superb Performances

TL;DR

This paper introduces superlubric nanogenerators (SLNGs) that leverage structural superlubricity to achieve high performance, durability, and sensitivity, enabling efficient energy harvesting from weak and low-frequency sources.

Contribution

It systematically analyzes three types of superlubric nanogenerators and demonstrates their superior performance and longevity compared to conventional nanogenerators.

Findings

SLNGs achieve three orders of magnitude higher current densities.

SLNGs can operate with external loads as low as ~1 μN.

Capacitor-based SLNGs are most competitive in performance and fabrication.

Abstract

Nanogenerators promise self-powered sensors and devices for extensive applications in internet of things, sensor networks, big data, personal healthcare systems, artificial intelligence, et al. However, low electric current densities and short product lifespans have blocked nanogenerators' applications. Here we show that structural superlubricity, a state of nearly zero friction and wear between two contacted solid surfaces, provides a revolutionary solution to the above challenge. We investigate three types of superlubric nanogenerators (SLNGs), namely the capacitor-based, triboelectric, and electret-based SLNGs, and systematically analyze the influences of material and structural parameters to these SLNGs' performances. We demonstrate that SLNGs can achieve not only enduring lifespans, but also superb performances - three orders of magnitude in current densities and output powers higher than those of conventional nanogenerators. Furthermore, SLNGs can be driven by very weak external loads (down to ~1 ${\mu}$N) in very low frequencies (down to ~1 ${\mu}$Hz), and are thus capable to harvest electric energies from an extremely board spectrum of environments and biosystems. Among the three types of SLNGs, the capacitor-based is synthetically most competitive in the senses of performance, fabrication and maintaining. These results can guide designs and accelerate fabrications of SLNGs toward real applications.