Fractional Fowler-Nordheim Law for Field Emission from Rough Surface with Nonparabolic Energy Dispersion

TL;DR

This paper develops a generalized Fowler-Nordheim equation accounting for rough surfaces and nonparabolic energy dispersion, improving the accuracy of field emission analysis from modern nanoscale materials.

Contribution

It introduces an analytical fractional-dimensional FN model that incorporates surface roughness and nonparabolic dispersion effects, extending traditional theories.

Findings

The model reduces to the classical FN equation for flat, parabolic materials.

It allows experimental determination of surface roughness parameters.

Application to data yields more accurate emission parameters.

Abstract

The theories of field electron emission from perfectly planar and smooth canonical surfaces are well understood, but they are not suitable for describing emission from rough, irregular surfaces arising in modern nanoscale electron sources. Moreover, the existing models rely on Sommerfeld's free-electron theory for the description of electronic distribution which is not a valid assumption for modern materials with nonparabolic energy dispersion. In this paper, we derive analytically a generalized Fowler-Nordheim (FN) type equation that takes into account the reduced space-dimensionality seen by the quantum mechanically tunneling electron at a rough, irregular emission surface. We also consider the effects of non-parabolic energy dispersion on field-emission from narrow-gap semiconductors and few-layer graphene using Kane's band model. The traditional FN equation is shown to be a limiting case of our model in the limit of a perfectly flat surface of a material with parabolic dispersion. The fractional-dimension parameter used in this model can be experimentally calculated from appropriate current-voltage data plot. By applying this model to experimental data, the standard field-emission parameters can be deduced with better accuracy than by using the conventional FN equation.