Selective Conduction of Organic Molecules via Free-Standing Graphene

TL;DR

This study investigates how different organic molecules move across graphene under thermal gradients, revealing selective conduction for aromatic compounds and novel collective behaviors at low temperatures.

Contribution

It demonstrates the selective conduction mechanism of aromatic molecules on graphene driven by thermal gradients and uncovers collective movement phenomena at low temperatures.

Findings

Aromatic molecules exhibit faster, selective conduction on graphene.

No ballistic transport observed even at single-molecule level.

Collective movement occurs at low temperatures with molecule aggregation.

Abstract

A race is held between ten species of organic gas molecules on a graphene substrate driven by thermal gradients via molecular dynamics. Fast conduction of the molecules is observed with selectivity for aromatic compounds. This selectivity stems from the fact that the planar structure of the aromatic molecule helps keep a shorter distance to the substrate, which is the key to the driving force at the gas-solid interface. The drift velocity monotonically increases with decreasing molecule density, with no ballistic transport observable even for a single molecule. A non-linear regime is discovered for the conduction of benzene molecules under large thermal gradients. At low temperature, molecules formed aggregation and move collectively along specific path in the graphene substrate.