Researchers at TU Delft have developed a highly sensitive and versatile hydrogen sensor that works at room temperature. The sensor is made of a thin layer of a material called tungsten trioxide.
Hydrogen has the potential to replace fossil fuels as the most important energy carrier in the near future. It has the highest energy per mass of any fuel and can be produced sustainably. However, it is also flammable, making sensors that can detect it an absolute necessity for the transition to a hydrogen economy. Various types of hydrogen sensors already exist, but most of these sensors require high temperatures in order to function. Researchers at TU Delft have now developed a sensor that works at room temperature.
A crystalline material
The new sensor is made of a material called tungsten trioxide. One of the properties of tungsten trioxide is that its crystal lattice structure contains a lot of open spaces. As a result, the material can easily be doped, which is the practice of changing its electronic properties by introducing other atoms.
“By itself, tungsten trioxide is an insulator”, said Giordano Mattoni, the lead author. “But when you dope it, you add electronic charges which turn the material into a different colour and also gradually change it into a metal. We wanted to try to dope thin films of tungsten trioxide with hydrogen gas to see if it could function as a sensor.”
It turns out that it can. The researchers first created thin sheets of tungsten trioxide using a method called pulsed laser deposition. That way, they were able to deposit single layers of the material onto a substrate one by one. “Using this method, we created sheets of tungsten trioxide with a thickness of only nine nanometres”, said Mattoni.
Room temperature operation
The researchers then put platinum droplets on top of the thin layers of tungsten trioxide. Platinum is well known to function as a catalyst which separates the hydrogen molecules into single hydrogen atoms. These atoms, the researchers observed, could then enter the lattice structure of tungsten trioxide, slowly turning it from an insulator into a metal. “This means that, by measuring the resistance of the material, we can determine the amount of hydrogen present in the environment”, Mattoni explained.
What sets this new hydrogen sensor apart from most other sensors is that it can be used at room temperature. “It is also much more sensitive than commercially available products and it can be reused in a matter of minutes”, Mattoni added. “Also, by increasing or decreasing the temperature of the sensor, the sensitivity range can be tuned for different applications.”
Finally, the thin film nature and the compatibility with current semiconductor technologies allow the sensor to be scaled up towards mass production. Mattoni and TU Delft have filed a patent application for this novel sensing technology.
“Single-crystal Pt-decorated WO3 Ultrathin Films: A Platform for Sub-ppm Hydrogen
Sensing at Room Temperature”, Giordano Mattoni, Bas de Jong, Nicola Manca, Massimo Tomellini and Andrea D. Caviglia