# Pressure-induced electro-switching of polymer/nano-graphene composites

**Authors:** Eirini Kolonelou, Anthony N. Papathanassiou, Elias Sakellis

arXiv: 1905.01451 · 2019-05-17

## TL;DR

This study investigates how applying pressure induces a reversible switch in electrical conductivity in polymer/nano-graphene composites, enabling a stable transition from conductor to insulator at specific pressures.

## Contribution

It demonstrates pressure-induced electro-switching behavior in polymer/nano-graphene composites and elucidates the underlying mechanisms affecting conductivity changes.

## Key findings

- Conductivity drops by two orders of magnitude at ~750 bars.
- The transition is stable over a temperature range above room temperature.
- The switching is controlled by competition between polarizability and inter-platelet separation.

## Abstract

The pressure and temperature dependency of the electrical conductivity of poly(vinyl alcohol)/poly(vinyl pyrrolidone) (1/1, w/w) and poly(vinyl alcohol) and composites with dispersed nano-graphene platelets were studied. Above the critical platelet fraction for electric charge percolation, the composites function as pressure-induced electro-switches. The conductor to insulator transition is optimally intense and stable. The electrical conductivity drops by two orders of magnitude at a critical pressure around 750 bars. The transition is stable over tenths of degrees above room temperature. The reduction of the conductivity upon pressure results from the competition between the pressure dependencies of the polarizability of the polymer matrix and the inter-platelet separation, respectively. Both contributions control the fluctuation induced tunneling of electrons through the polymer barrier separating adjusting conductive platelets. The role of the local electric field at the polymer-platelet interfaces by assisting tunneling is suppressed by the decrease of the polarizability upon pressure.

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Source: https://tomesphere.com/paper/1905.01451