Higher order curvature corrections to the field emission current density

Abstract

A simple expression for the Gamow factor is obtained using a second order curvature corrected tunneling potential. Our results show that it approximates accurately the `exact-WKB' transmission coefficient obtained by numerically integrating over the tunneling region to obtain the Gamow factor. The average difference in current density using the respective transmission coefficients is about 1.5 \%, across a range of work-functions φ ∈ [3-5.5]eV, Fermi energy EF in [5-10]eV, local electric fields El in[3-9]eV and radius of curvature R ≥ 5nm). An easy-to-use correction factor λP is also provided to approximately map the `exact-WKB' current density to the `exact' current density in terms of EF/φ. The average error on using λP is found to be around 3.5\%. This is a vast improvement over the average error of 15\% when λP = 1. Finally, an analytical expression for the curvature-corrected current density is obtained using the Gamow factor. It is found to compare well with the `exact-WKB' current density even at small values of local electric field and radius of curvature.