Neutrinos news, articles and features | New Scientist /topic/neutrinos/ Science news and science articles from New Scientist Wed, 11 Mar 2026 16:17:05 +0000 en-US hourly 1 https://wordpress.org/?v=7.0.1 242057827 Why a Peruvian mountain is becoming an ‘impossible’ particle detector /article/2517730-why-a-peruvian-mountain-is-becoming-an-impossible-particle-detector/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Wed, 11 Mar 2026 16:00:16 +0000 /?post_type=article&p=2517730 2517730 Ghostly particles might just break our understanding of the universe /article/2509266-ghostly-particles-might-just-break-our-understanding-of-the-universe/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Mon, 05 Jan 2026 08:00:49 +0000 /?post_type=article&p=2509266 2509266 We may have finally solved an ultra-high-energy cosmic ray puzzle /article/2487950-we-may-have-finally-solved-an-ultra-high-energy-cosmic-ray-puzzle/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Fri, 11 Jul 2025 19:30:28 +0000 /?post_type=article&p=2487950 2487950 ‘Impossible’ particle that hit Earth may have been dark matter /article/2483828-impossible-particle-that-hit-earth-may-have-been-dark-matter/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Wed, 11 Jun 2025 11:09:15 +0000 /?post_type=article&p=2483828 2483828 The ‘impossible’ particle hinting at the universe’s biggest secrets /article/2478036-the-impossible-particle-hinting-at-the-universes-biggest-secrets/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Mon, 28 Apr 2025 15:00:00 +0000 http://mg26635410.700 2478036 Why particle physicists are going wild for a record-breaking neutrino /article/2472340-why-particle-physicists-are-going-wild-for-a-record-breaking-neutrino/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Wed, 19 Mar 2025 18:00:00 +0000 http://mg26535350.100 2472340 Record-breaking neutrino spotted tearing through the Mediterranean Sea /article/2468121-record-breaking-neutrino-spotted-tearing-through-the-mediterranean-sea/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Wed, 12 Feb 2025 16:00:35 +0000 /?post_type=article&p=2468121
Part of the KM3NeT neutrino detector on the seafloor
KM3NeT

A shockingly powerful neutrino that ripped through a new particle detector in the Mediterranean Sea has taken physicists by surprise, and it could be a first tantalising glimpse into some of the universe’s most cataclysmic events, such as the merging of supermassive black holes.

Neutrinos, sometimes referred to as “ghost particles”, barely interact with most matter because they are nearly massless and have no electric charge. This means that neutrino detectors typically incorporate vast amounts of dense substance, such as water or ice, in the hopes that a powerful neutrino might knock into an atom and produce a shower of particles that reveal tell-tale signs of its existence.

at the Centre for Particle Physics of Marseille in France and his colleagues have done just that, spotting the most energetic neutrino ever seen. The team used the cubic kilometre neutrino telescope (KM3NeT), a pair of detector arrays at the bottom of the Mediterranean Sea, which picked up the neutrino on 13 February 2023. The detector was only 10 per cent complete at the time, so it took Dornic and his team by surprise.

“First, we were confused,” he says. “When we realised more and more that this event is truly exceptional, we were really excited.”

The signal looked promising, showing up as a nearly horizontal bright line in the detector. The researchers think this was created by small, electron-like particles called muons that were produced in the wake of the neutrino slamming through the detector and gave off light that KM3NeT’s detectors could pick up.

When the researchers first tentatively announced the result in 2024, they were still calculating the exact energy of the particle. “They were clearly surprised that they’ve seen something this high energy, so their simulations of neutrinos didn’t go that high in energy yet, they hadn’t expected to see anything this energetic,” says at the University of Oxford.

To confirm the result, the researchers had to first carefully account for the effects of other sources that could light up their detectors, such as neutrinos produced when charged particles from space, called cosmic rays, strike Earth’s atmosphere. Such signals are thought to outnumber higher energy neutrinos from more distant cosmic sources by a billion to one.

Now, they have calculated that the neutrino had an energy of 120 peta-electron volts (PeV). This is around 10 times higher than the previous record holder, discovered by the IceCube Neutrino Observatory in Antarctica. This PeV energy range is also thousands of times more than the most energetic particles produced at accelerators on Earth, such as the Large Hadron Collider at CERN.

Detecting such high-energy neutrinos can give us unique insights into the events that produce them, such as black holes accreting matter or supernova explosions, which themselves give off cosmic rays that produce neutrinos as they are made. “Cosmic rays are charged, and we lose most of their original formation location as they traverse interstellar space, but the neutrinos will point straight back,” says Wascko.

Dornic says that in this case, following the neutrino back leads to a relatively large patch of space, making it difficult to locate an exact source, but planned improvements to the telescope should allow them to pinpoint an object should a similarly powerful neutrino be spotted in future.

Journal reference:

Nature

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How big is a neutrino? We’re finally starting to get an answer /article/2468207-how-big-is-a-neutrino-were-finally-starting-to-get-an-answer/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Wed, 12 Feb 2025 16:00:31 +0000 /?post_type=article&p=2468207
Pinning down the size of the neutrino is a tricky task
agsandrew/Shutterstock
The first direct measurement of the size of the neutrino, a fundamental particle, suggests they are at least larger than an atomic nucleus – but they could potentially be trillions of times larger. Part of the problem in answering this question is that, rather than being spherical, quantum mechanics tells us that particles are inherently fuzzy waves, moving and vibrating as they travel through space. Physicists mark the boundaries of a particle, and thus its size, by looking for its wave packet, an area inside which the wave vibrates strongly, and beyond which it sharply trails off. For neutrinos, measuring the wave packet is particularly challenging because these particles rarely interact with normal matter. Until now, we have only calculated the wave packet’s size indirectly, with estimates spanning a range of 13 orders of magnitude – from smaller than an atomic nucleus to as large as a couple of metres, or 10 trillion times bigger. Now, at the Colorado School of Mines and his colleagues have made the first direct measurement of the wave packet, finding that neutrinos must be at least hundreds of times larger than the previous smallest estimate, making them larger than typical atomic nuclei. To do this, Smolsky and his team measured radioactive beryllium as it decayed into lithium, a process called electron capture. When this happens, an electron in the beryllium atom combines with a proton in its nucleus, producing a neutron. This transforms the beryllium atom into lithium, producing a kick of energy that fires the atom in a certain direction and generating a neutrino that fires in the opposite direction to balance the momentum. By putting the beryllium inside very sensitive superconducting detectors and studying it using a particle accelerator, they could then measure the lithium atoms extremely precisely and infer the neutrino’s properties. The researchers found that the neutrinos were at least 6.2 picometres, which is hundreds of times larger than the atomic nucleus. “It was a little bit surprising,” says Smolsky. “When I think of an electron capture process, I imagine it within the nucleus because the electron has to overlap with a nucleus. But the limit we showed says that the size of the neutrino is actually much larger than the nucleus itself when it comes out.”
“Technically, this is a very difficult measurement,” says at Johannes Gutenberg University in Mainz, Germany. “They used a really very neat method to make a precision measurement, something which I thought you could never do.” Measuring the size of the neutrino wave packet is important for building future neutrino detectors capable of precisely measuring how often neutrinos switch, or oscillate, between three different types, says Weber. These neutrino oscillations are key to working out why there is more matter than antimatter in the universe, but they can only be precisely measured if the neutrino is above a certain size. If it is too small, then the three different types of neutrino, each of a different mass, will spill over the edges of the neutrino wave packet, and mess up the measurements.
Journal reference:

Nature

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A tale of two mysteries: ghostly neutrinos and the proton decay puzzle /article/2420266-a-tale-of-two-mysteries-ghostly-neutrinos-and-the-proton-decay-puzzle/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Wed, 06 Mar 2024 18:00:00 +0000 http://mg26134810.200 2420266 Supernova neutrinos could break physics – if we can make sense of them /article/2410317-supernova-neutrinos-could-break-physics-if-we-can-make-sense-of-them/?utm_campaign=RSS|NSNS&utm_content=neutrinos&utm_medium=RSS&utm_source=NSNS Wed, 03 Jan 2024 16:00:00 +0000 http://mg26134722.200 2410317