Researchers discover ultra-hard material that could rival diamond
An international team of scientists looked at carbon nitrides.
Your support helps us to tell the story
From reproductive rights to climate change to Big Tech, The Independent is on the ground when the story is developing. Whether it's investigating the financials of Elon Musk's pro-Trump PAC or producing our latest documentary, 'The A Word', which shines a light on the American women fighting for reproductive rights, we know how important it is to parse out the facts from the messaging.
At such a critical moment in US history, we need reporters on the ground. Your donation allows us to keep sending journalists to speak to both sides of the story.
The Independent is trusted by Americans across the entire political spectrum. And unlike many other quality news outlets, we choose not to lock Americans out of our reporting and analysis with paywalls. We believe quality journalism should be available to everyone, paid for by those who can afford it.
Your support makes all the difference.Scientists have discovered a near-unbreakable substance that could rival diamond as the hardest material on Earth.
Researchers found that when carbon and nitrogen molecules were subjected to extreme heat and pressure, the resulting materials, known as carbon nitrides, were tougher than cubic boron nitride, the second hardest material after diamond.
Experts said the breakthrough opens doors for multifunctional materials to be used for industrial purposes including protective coatings for cars and spaceships, high-endurance cutting tools, solar panels and photodetectors.
Materials researchers have been attempting to unlock the potential of carbon nitrides since the 1980s, when scientists first noticed their exceptional properties, including high resistance to heat.
Yet after more than three decades of research and multiple attempts to synthesize them, no credible results had been reported.
However an international team of scientists – led by researchers from the Centre for Science at Extreme Conditions at the University of Edinburgh and experts from the University of Bayreuth, Germany, and the University of Linkoping, Sweden – has now achieved a breakthrough.
Dr Dominique Laniel, future leaders fellow in the Institute for Condensed Matter Physics and Complex Systems, School of Physics and Astronomy, at the University of Edinburgh, said: “Upon the discovery of the first of these new carbon nitride materials, we were incredulous to have produced materials researchers have been dreaming of for the last three decades.
“These materials provide strong incentive to bridge the gap between high pressure materials synthesis and industrial applications.”
The research team subjected various forms of carbon nitrogen molecules to pressures of between 70 and 135 gigapascals – around one million times our atmospheric pressure – while heating it to temperatures of more than 1,500C.
To identify the atomic arrangement of the compounds under these conditions, the samples were illuminated by an intense X-ray beam at three particle accelerators – the European Synchrotron Research Facility in France, the Deutsches Elektronen-Synchrotron in Germany, and the Advanced Photon Source based in the United States.
Researchers discovered that three carbon nitride compounds were found to have the necessary building blocks for super-hardness.
They found all three compounds retained their diamond-like qualities when they returned to ambient pressure and temperature conditions.
Further calculations and experiments suggest the new materials contain additional properties including photoluminescence and high energy density, where a large amount of energy can be stored in a small amount of mass.
Researchers say the potential applications of these ultra-incompressible carbon nitrides is vast, potentially positioning them as ultimate engineering materials to rival diamonds.
Dr Florian Trybel, assistant professor in the Department of Physics, Chemistry and Biology at the University of Linkoping, said: “These materials are not only outstanding in their multi-functionality, but show that technologically relevant phases can be recovered from a synthesis pressure equivalent to the conditions found thousands of kilometres in the Earth’s interior.
“We strongly believe this collaborative research will open up new possibilities for the field.”
The research, published in Advanced Materials, was funded by the UK Research and Innovation Future Leaders Fellowships scheme and European research grants.