# Restoring observed classical behavior of the carbon nanotube field   emission enhancement factor from the electronic structure

**Authors:** Caio P. de Castro, Thiago A. de Assis, Roberto Rivelino, Fernando de, B. Mota, Caio M. C. de Castilho, Richard G. Forbes

arXiv: 1812.00783 · 2019-10-31

## TL;DR

This paper demonstrates that quantum-mechanical density functional theory calculations can reproduce the classical constant field enhancement factor observed experimentally in carbon nanotube field emission, bridging the gap between quantum and classical models.

## Contribution

The study shows that using DFT to derive induced charge distributions yields FEF values independent of macroscopic fields, aligning quantum results with classical models and experimental observations.

## Key findings

- DFT-derived local induced FEFs are field-independent
- Quantitative agreement between classical and DFT FEFs
- Quantum models can replicate classical constant FEF behavior

## Abstract

Experimental Fowler-Nordheim plots taken from orthodoxly behaving carbon nanotube (CNT) field electron emitters are known to be linear. This shows that, for such emitters, there exists a characteristic field enhancement factor (FEF) that is constant for a range of applied voltages and applied macroscopic fields $F_\text{M}$. A constant FEF of this kind can be evaluated for classical CNT emitter models by finite-element and other methods, but (apparently contrary to experiment) several past quantum-mechanical (QM) CNT calculations find FEF-values that vary with $F_\text{M}$. A common feature of most such calculations is that they focus only on deriving the CNT real-charge distributions. Here we report on calculations that use density functional theory (DFT) to derive real-charge distributions, and then use these to generate the related induced-charge distributions and related fields and FEFs. We have analysed three carbon nanostructures involving CNT-like nanoprotrusions of various lengths, and have also simulated geometrically equivalent classical emitter models, using finite-element methods. We find that when the DFT-generated local induced FEFs (LIFEFs) are used, the resulting values are effectively independent of macroscopic field, and behave in the same qualitative manner as the classical FEF-values. Further, there is fair to good quantitative agreement between a characteristic FEF determined classically and the equivalent characteristic LIFEF generated via DFT approaches. Although many issues of detail remain to be explored, this appears to be a significant step forwards in linking classical and QM theories of CNT electrostatics. It also shows clearly that, for ideal CNTs, the known experimental constancy of the FEF value for a range of macroscopic fields can also be found in appropriately developed QM theory.

## Full text

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## Figures

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## References

22 references — full list in the complete paper: https://tomesphere.com/paper/1812.00783/full.md

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Source: https://tomesphere.com/paper/1812.00783