# Effect of nano-carbon dispersions on signal in silicon-based sensor   structure with photoelectrical transducer principle

**Authors:** Anton I. Manilov, Aleksey V. Kozinetz, Sergiy V. Litvinenko, Valeriy, A. Skryshevsky, Mohammed Al Araimi, Alex Rozhin

arXiv: 1905.07179 · 2019-05-20

## TL;DR

This study explores how different nano-carbon dispersions affect the signal behavior in silicon-based photoelectrical sensors, revealing unique signatures and dynamics linked to each nano-carbon type.

## Contribution

It introduces a novel sensor structure capable of identifying nano-carbon species through their distinct photocurrent signatures and temporal evolution.

## Key findings

- Different nano-carbon species exhibit unique photocurrent signatures.
- Nano-carbon particles influence surface band-bending and recombination parameters.
- The sensor can distinguish nano-carbon types based on photocurrent behavior.

## Abstract

We identified different nano-carbon species such as graphene nanoplatelets, graphite flakes and carbon nanotubes dispersed in N-methyl-2-pyrrolidone using a novel sensor structure based on a "deep" silicon barrier working as a photoelectrical transducer. Each nano-carbon particle has specific signature in both 2D photocurrent distribution and photocurrent dependences on bias changing surface band-bending. Additionally, all nano-carbon particles have characteristic features in the time-dependent evolution of photocurrent. The obtained results can be explained by the influence of nano-carbon molecules' local electric field on the recombination parameters of defect centers on the silicon surface.

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Source: https://tomesphere.com/paper/1905.07179