Laser-induced modification of graphene in the presence of ethanol on a graphene–substrate interface

We have studied the effect that the substitution of an organic substance (ethanol) for water adsorbate on a CVD graphene – SiO₂/Si interface has on the laser-induced modification of graphene and graphene structures on the SiO₂ film. Scanning probe microscopy has been used to analyse changes in the electronic properties of graphene structures on a hydrophilic substrate in the presence of ethanol and as a result of a laser-induced spatial redistribution of a water–alcohol adsorbate on the interface. It has been demonstrated experimentally that ethanol substitution for water adsorbate leads to an increase in the surface potential of the graphene, which is equivalent to a reduction in its work function with respect to the original level under normal conditions at a relative humidity of air from 30% to 60%. In the laser irradiation zone, we observe an additional increase in surface potential by 30–50 mV. Thus, ethanol makes it possible to tune the laser-induced electronic properties of graphene on a substrate. In addition, it has been shown that the intercalation of ethanol molecules leads to severe temporal instability of the physical properties of graphene structures produced by local laser irradiation. We have demonstrated the possibility of information 'rewriting' by low-intensity laser pulses in microregions with a changed surface potential in the presence of ethanol.