Paper detail

Defect-induced Fermi level pinning and suppression of ambipolar behaviour in graphene

We report on systematic study of electronic transport in low-biased, disordered graphene nanowires. We reveal the emergence of unipolar transport as the defect concentration increases beyond 0.3\% where an almost insulating behaviour is observed on n-type channels whilst a metallic behaviour is observed in p-type channels. The conductance shows a plateau that extends through the entire side above the Dirac point (n-type) and the conductivity coincides with the minimum conductivity at the Dirac point. The minimum conductivity decreases with increasing defect concentration pointing out towards the absence of zero energy modes in the disordered samples. Raman spectroscopy and X-ray photoemission spectroscopy were used to probe the nature of the defects created by helium ion irradiation and revealed the presence of oxygen-carbon bonds as well as the presence of $sp^3$ configuration uncovered from the C KLL Auger spectrum. The observed behaviour is attributed to the dangling bonds created by sputtering of carbon atoms in graphene lattice by bombarding helium ions. The dangling bonds act as charge traps, pinning the Fermi level to the Dirac point.