
A particle detector made from extremely thin sheets of carbon may be able to spot never-before-seen neutrinos from the time of the big bang. If the design works, detecting these so-called ultra-low energy neutrinos could help us better understand the first moments of the universe.
Detecting any neutrinos is challenging because they normally move through matter without affecting it – trillions of them are passing through you right now. They are some of the most abundant particles, but they are nearly massless and don’t have electric charge. To spot even high energy neutrinos created in cataclysmic events like explosions of nearby stars, researchers have to build huge detectors kilometres across.
Hugo Terças at the University of Lisbon in Portugal and Carlo Alfisi at the Polytechnic University of Milan in Italy have created with a design for a much smaller detector that would be able to spot ultra-low energy neutrinos. Their detector would be shaped like an elongated box only a few centimetres in size and composed of dozens or more layers of graphene – essentially carbon sheets that are only one atom thick.
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The pair calculated that a few thousand ultra-low energy neutrinos entering the detector would make the electrons move in waves of a liquid-like state called plasma. From the way the plasma behaves, they would be able to deduce how fast and how heavy the neutrinos are.
Read more: Graphene: What it’s good for
Electrons in materials other than graphene wouldn’t combine into plasma after interacting with low energy neutrinos. “Physics-wise, we had to think completely out of the box here,” says Terças. So far, researchers have only built detectors for very energetic neutrinos.
“This is really kind of a new way of listening to the universe,” says Christopher Tully at Princeton University. He and his collaborators are in the early stages of building a different detector where neutrinos collide with tritium – the radioactive version of hydrogen – and make it decay into helium.
Actually building the new graphene-based detector will require advances in engineering and material science, says Terças. For instance, it is currently difficult to make centimetre-sized graphene sheets free of imperfections. The blemishes would influence the plasma’s behaviour and consequently make neutrino detection glitchy.
Irene Tamborra at the University of Copenhagen in Denmark says the detector could be used to test theories about the early universe. Where neutrinos were and how fast they were moving right after the big bang may have influenced where whole galaxies formed later. Currently, physicists also have many questions about neutrinos themselves, Tamborra says, like what exactly their mass is and whether they are their own antiparticles.
ڱԳ:arXiv,
Article amended on 16 May 2022
We have corrected the description of what happens when neutrinos enter the detector.