# Device Chemistry of Graphene Transistors

**Authors:** B. C. Worley, S. Kim, T.J. Ha, S. Park, R. Haws, P. Rossky, D., Akinwande, and A. Dodabalapur

arXiv: 1906.05734 · 2019-06-14

## TL;DR

This paper reviews methods to improve graphene transistor performance by mitigating charged impurities and defects, demonstrating that polar capping layers and vapors can electrostatically screen impurities, enhancing electrical properties.

## Contribution

It introduces and evaluates the effectiveness of polar capping layers and vapors in reducing impurity effects in graphene transistors, a novel approach for device optimization.

## Key findings

- Polar capping layers improve mobility and on/off ratio.
- Vapor-phase polar molecules enhance electrical characteristics.
- Improvements are reversible and scale with dipole moment.

## Abstract

Graphene is an attractive material for microelectronics applications, given such favourable electrical characteristics as high mobility, high operating frequency, and good stability. If graphene is to be implemented in electronic devices on a mass scale, then it must be compatible with existing semiconductor industry fabrication processes. Unfortunately, such processing introduces defects and impurities to the graphene, which cause scattering of the charge carriers and changes in doping level. Scattering results in degradation of electrical performance, including lower mobility and Dirac point shifts. In this paper, we review methods by which to mitigate the effects of charged impurities and defects in graphene devices. Using capping layers such as fluoropolymers, statistically significant improvement of mobility, on/off ratio, and Dirac point voltage for graphene FETs have been demonstrated. These effects are also reversible and can be attributed to the presence of highly polar groups in these capping layers such as carbon-fluoride bonds in the fluoropolymer acting to electrostatically screen charged impurities and defects in or near the graphene. In other experiments, graphene FETs were exposed to vapour-phase, polar, organic molecules in an ambient environment. This resulted in significant improvement to electrical characteristics, and the magnitude of improvement to the Dirac point scaled with the dipole moment of the delivered molecule type. The potential profile produced in the plane of the graphene sheet by the impurities was calculated to be significantly reduced by the presence of polar molecules. We present strong evidence that the polar nature of capping layers or polar vapour molecules introduced to the surface of a graphene FET act to mitigate detrimental effects of charged impurities/defects.

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Source: https://tomesphere.com/paper/1906.05734