Organic Hydrogen Sensors for Potential Use in Safety-Critical Environments

TL;DR

This paper introduces a novel organic hydrogen sensor using organic molecules without catalytic metals, capable of real-time monitoring in fuel cell environments with tunable response times.

Contribution

It presents a new organic hydrogen sensing mechanism based on $ ext{Alq}_3$, enabling sensitive, linear detection across various conditions without catalytic metals.

Findings

Sensor shows up to 3.5% response at 100% hydrogen.

Resistivity increases linearly with hydrogen concentration.

Sensor response is tunable with magnetic fields.

Abstract

Accurate monitoring of the hydrogen concentration is critical for optimizing fuel cell performance, minimizing purge losses, and reducing long-term degradation. Conventional hydrogen sensors often rely on catalytic materials and face limitations such as the need of oxygen purging when operated in fuel cell environments. Here, we report the discovery of a novel hydrogen-sensing mechanism based on organic molecules, without the use of catalytic metals. The sensor is based on a typical vertical stack geometry, containing $\mathrm{Alq_3}$ as active organic material. Upon exposure to hydrogen, the device shows an increase in resistivity, yielding a reliable sensor signal that varies linearly with hydrogen concentration, temperature, and humidity, and exhibits a relative response of up to 3.5 % at 100 %vol hydrogen. By exposing the sensor to an external magnetic field, the rise and fall times of the sensor response were found to be tunable. This novel organic sensor demonstrates sensitivity across a wide range of hydrogen concentrations under fuel cell-relevant conditions and beyond. This new class of hydrogen sensors with high miniaturization potential and cost efficiency paves the way for real-time hydrogen monitoring and advanced control strategies in fuel cells, the chemical industry, or energy storage applications.