# Extraction of the short-range defect potential parameters from available   experimental data on the graphene resistance

**Authors:** N.E. Firsova. S.A. Ktitorov

arXiv: 1907.10894 · 2019-07-26

## TL;DR

This paper develops models of short-range scattering potentials in graphene to interpret experimental resistance data, enabling extraction of potential parameters crucial for high-mobility applications.

## Contribution

It introduces explicit formulas for short-range scattering potentials in graphene and demonstrates their application to experimental resistance data to determine potential parameters.

## Key findings

- Theoretical formulas match experimental resistance measurements.
- Parameters of short-range potentials can be extracted from resistance data.
- Models are applicable to high-mobility, suspended graphene samples.

## Abstract

We consider a problem of obtaining information about the scattering potentials of the monolayer graphene sample using available experimental data on its resistance. We have in mind a development of the study describing super-high mobility electrons in suspended samples without chemical doping. As far as practical absence of the doping impurities in this case makes the Coulomb scattering negligible, we consider models of the short-range scattering potentials. The model of short-range potential is assumed to be supported by the close vicinity of the ring or the circumference of a circle. The diameter of circles is supposed to be of the order of the crystal lattice spacing. The empty core of the model potential guarantees the suppression of nonphysical shortwave modes. Two models are investigated: the delta function on the circumference of a circle (delta shell) and the annual well. An advantage of the former is simplicity, while a virtue of the latter is regularity. We consider scattering of electrons by these potentials and obtain exact explicit formulae for the scattering data. We here discuss application of these formulae for calculation of observables. Namely, we analyze the contribution of this scattering into the graphene resistance and plot the resistivity as a function of the Fermi energy according to our theoretical formulae. The obtained results are consistent with experiment, where the resistance was measured as a function of the Fermi momentum on the suspended annealed graphene. This fact gives a possibility to find parameters of the modeled potential on the base of the available experimental data on resistance of the suspended graphene sample with the gate voltage controlled Fermi level position. It is clear to be very important for applications.

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Source: https://tomesphere.com/paper/1907.10894