# Dipolar Switching of Charge-Injection Barriers at   Electrode/Semiconductor Interfaces as a Mechanism for Water-Induced   Instabilities of Organic Devices

**Authors:** Ryo Nouchi

arXiv: 1902.01640 · 2020-01-28

## TL;DR

This paper reveals that water molecules induce dipolar switching at electrode/organic interfaces, causing instability in organic electronic devices by altering charge-injection barriers, with reversible diode-like behavior demonstrated.

## Contribution

It introduces a novel water-induced dipolar switching mechanism at electrode/semiconductor interfaces that explains operational instabilities in organic devices.

## Key findings

- Water penetration causes charge-injection barrier changes.
- Electric field orients water dipoles, switching barrier height.
- Device exhibits a high current switching ratio of 267.

## Abstract

An electrode contact-related mechanism for the operational instability of organic electronic devices is proposed and confirmed via observation of a water-induced change in charge-injection barrier eights at the electrode/organic-semiconductor interfaces. Water molecules in air penetrate into the organic crystal via diffusion, and an external electric field orients the electric dipole of the water molecules at the electrode surfaces, leading to dipolar switching of the charge-injection barrier height. As a result of the switching, current-voltage curves of two-terminal Au-rubrene-Au devices change from symmetric to asymmetric, showing diode-like rectification and reversible switching of the diode polarity. The device shows the highest current switching ratio of 267 for the switching voltage of 3 V, corresponding to an electrode work function change of >144 meV. The mechanism proposed herein will be important especially for short-channel organic devices, which are indispensable for applications such as organic integrated circuits.

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Source: https://tomesphere.com/paper/1902.01640