Electromechanical actuation of pristine graphene and graphene oxide: origin, optimization, and comparison

TL;DR

This paper reviews recent advances in graphene and graphene oxide as electromechanical actuators, focusing on their physical mechanisms, optimization, and potential for small-scale device applications.

Contribution

It provides an in-depth analysis of actuation mechanisms in graphene materials and insights for optimizing their performance at micro and nano scales.

Findings

Different physical mechanisms of graphene actuation identified

Insights into optimizing graphene-based actuators for small scales

Comparison between pristine graphene and graphene oxide performance

Abstract

It is well recognized that the miniaturization of electromechanical devices will bring a revolution to humanity in the coming decades synonymous with the effects of miniaturizing electronic devices in those previous. An electromechanical actuator - a device that converts electrical energy to mechanical deformation or motion - is the core component of many such devices. Consequently, research interrogating mili-, micro-, and nano-actuation has, and will continue to become increasingly essential. The challenge is that behaviour of actuators at small size scales vastly differs to those at the macroscale. We cannot simply shrink the size of conventional actuators at the macroscale down to the micro/nanoscale. In addition, conventional actuation materials (such as piezoelectric ceramics and shape memory alloys) have poor properties and performances when fabricated at a small length scale. There is an urgent need to discover novel actuation materials at small length scale. This paper will review recent advances in graphene-based actuation materials. We will focus on different actuation physical mechanisms of this most well-known two-dimension material. The in-depth physical understanding and insights will lay the ground for further optimization/development of graphene-based actuators. They may also provide valuable knowledge for the design and development of other two-dimensional actuation materials and actuators.