Laser Exfoliation of Graphene from Graphite

TL;DR

This paper introduces a laser-based, chemical-free method for exfoliating graphene from graphite, combining experimental laser irradiation with molecular dynamics simulations to optimize the process for large-scale industrial use.

Contribution

It presents a novel laser impulse technique for graphene exfoliation and develops a simulation framework to understand the process, advancing scalable, chemical-free graphene production.

Findings

Laser irradiation successfully produces graphene layers from graphite.

Higher laser fluence increases graphene yield and layer exfoliation.

Simulation confirms single-layer graphene formation within specific laser power ranges.

Abstract

Synthesis of graphene with reduced use of chemical reagents is essential for manufacturing scale-up and to control its structure and properties. In this paper, we report on a novel chemical-free mechanism of graphene exfoliation from graphite using laser impulse. Our experimental setup consists of a graphite slab irradiated with an Nd:YAG laser of wavelength 532 nm and 10 ns pulse width. The results show the formation of graphene layers with conformational morphology from electron microscopy and Raman spectra. Based on the experimental results, we develop a simulation set up within the framework of the molecular dynamics that supplies the laser-induced electromagnetic energies to atoms in the graphite slab. We investigate the influence of different laser fluence on the exfoliation process of graphene. The variations in inter-layer interaction energy and inter-layer distance are the confirmative measures for the possible graphene layer formation. The simulation results confirm the exfoliation of a single layer graphene sheet for the laser power ranging from 100x10^(-14) to 2000x10^(-14) J/nm2. With an increase of laser fluence from 2000x10^(-14) to 4000x10^(-14) J/nm2, there is an increase in the graphene yield via the layer-after-layer exfoliation. The bridging bond dynamics between the successive graphene layers govern the possibility of second-layer exfoliation. The experimental and simulation observations are useful and promising for producing chemical-free graphene on a large scale for industrial and commercial applications.