Low temperature electrical transport in microwave plasma fabricated free-standing graphene and N-graphene sheets

In this paper, the electrical transport in free-standing graphene and N-graphene sheets fabricated by a microwave plasma-based method is addressed. Temperature-dependent resistivity/conductivity measurements are performed on the graphene/N-graphene sheets compressed in pellets. Different measurement configurations reveal directional dependence of current flow-the room-temperature conductivity longitudinal to the pellet's plane is an order of magnitude higher than the transversal one, due to the preferential orientation of graphene sheets in the pellets. SEM imaging confirms that the graphene sheets are mostly oriented parallel to the pellet's plane and stacked in agglomerates. The high longitudinal electrical conductivity with values on the order of 10(3) S/m should be noted. Further, the current flow mechanism revealed from resistivity-temperature dependences from 300K down to 10K shows non-metallic behavior manifested with an increasing resistivity with decreasing the temperature dp/dT < 0) usually observed for insulating or localized systems. The observed charge transport shows variable range hopping at lower temperatures and thermally activated behaviour at higher temperatures. This allows us to attribute the charge transport mechanism to a partially disordered system in which single graphene sheets are placed predominantly parallel to each other and stacked together.

Automated summary

This paper investigates the electrical transport in free-standing graphene and N-graphene sheets fabricated by a microwave plasma-based method. Temperature-dependent resistivity/conductivity measurements are performed on the compressed graphene/N-graphene sheets, revealing directional dependence of current flow. SEM imaging confirms the preferential orientation of graphene sheets in the pellets. The observed charge transport mechanism is attributed to a partially disordered system with parallel placement and stacking of single graphene sheets.