Inspired by the surface of butterfly wings, researchers have developed a light-activated hydrogen sensor that produces ultra-precise results at room temperature.
The technology can detect hydrogen leaks well before they pose safety risks and can measure tiny amounts of the gas on people’s breath, for diagnosing gut disorders.
Commercial hydrogen sensors only work at temperatures of 150C or higher, but the prototype developed by researchers at RMIT University is powered by light instead of heat.
The sensor, based on bumpy microstructures that imitate the surface of butterfly wings, is detailed in a new study published in the journal ACS Sensors.
Co-lead researcher Dr Ylias Sabri said the prototype was scalable, cost-effective and offered a total package of features that could not be matched by any hydrogen sensor currently on the market.
“Some sensors can measure tiny amounts, others can detect larger concentrations; they all need a lot of heat to work,” Sabri said.
“Our hydrogen sensor can do it all – it’s sensitive, selective, works at room temperature and can detect across a full range of levels.”
The sensor can detect hydrogen at concentrations from as little as 10 parts per million molecules (for medical diagnoses) to 40,000 parts per million (the level where the gas becomes potentially explosive).
Co-lead researcher Dr Ahmad Kandjani said the broad detection range made it ideal for both medical use and boosting safety in the emerging hydrogen economy.
“Hydrogen has potential to be the fuel of the future but we know safety fears could affect public confidence in this renewable energy source,” he said.
“By delivering precise and reliable sensing technology that can detect the tiniest of leaks, well before they become dangerous, we hope to contribute to advancing a hydrogen economy that can transform energy supplies around the world.”
Butterfly bumps: How the sensor works
The innovative core of the new sensor is made up of tiny spheres known as photonic or colloidal crystals.
These hollow shapes, similar to the miniscule bumps found on the surface of butterfly wings, are highly ordered structures that are ultra-efficient at absorbing light.
That efficiency means the new sensor can draw all the energy it needs to operate from a beam of light, rather than from heat.
PhD researcher and first author Ebtsam Alenezy said the room-temperature sensor was safer and cheaper to run, compared to commercial hydrogen sensors that typically operate at 150C to 400C.
“The photonic crystals enable our sensor to be activated by light and they also provide the structural consistency that’s critical for reliable gas sensing,” she said.
“Having a consistent structure, consistent fabrication quality and consistent results are vital – and that’s what nature has delivered for us through these bioinspired shapes.
“The well-developed fabrication process for photonic crystals also means our technology is easily scalable to industrial levels, as hundreds of sensors could be rapidly produced at once.”
To make the sensor, an electronic chip is first covered with a thin layer of photonic crystals and then with a titanium palladium composite.
When hydrogen interacts with the chip, the gas is converted into water. This process creates an electronic current and by measuring the magnitude of the current, the sensor can tell precisely how much hydrogen is present.
Unlike many commercial sensors that struggle in the presence of nitrogen oxide, the new technology is highly selective so it can accurately isolate hydrogen from other gases.
The researchers acknowledge the support of the RMIT Microscopy and Microanalysis Facility (RMMF), the RMIT MicroNano Research Facility (MNRF), RMIT Enabling Capability Platforms (ECP) and Al Jouf University (Saudi Arabia) and the Saudi Arabian Cultural Mission (SACM) in Australia, which have funded Alenezy’s doctoral research.
‘Low temperature hydrogen sensor: Enhanced performance enabled through photoactive Pd-decorated TiO2 colloidal crystals’, with corresponding author Bhargava and co-authors Dr Samuel Ippolito, Dilek Korcoban and Syed Rashid, is published in ACS Sensors (DOI: 10.1021/acssensors.0c01387).
Story: Gosia Kaszubska