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Fermilab: Muon g-2 announces most precise measurement of the magnetic anomaly of the muon
The third and final result, based on the last three years of data, is in perfect agreement with the experiment's previous results, further solidifying the experimental world average. This long-awaited value will be the world's most precise measurement of the muon magnetic anomaly for many years to come. Muon g-2 ring Results plot graph Batavia, Ill., June 04, 2025 (GLOBE NEWSWIRE) -- Scientists working on the Muon g-2 experiment, hosted by the U.S. Department of Energy's Fermi National Accelerator Laboratory, have released their third and final measurement of the muon magnetic anomaly. This value is related to g-2, the experiment's namesake measurement. The final result agrees with their published results from 2021 and 2023 but with a much better precision of 127 parts-per-billion, surpassing the original experimental design goal of 140 parts-per-billion. 'The anomalous magnetic moment, or g–2, of the muon is important because it provides a sensitive test of the Standard Model of particle physics. This is an exciting result and it is great to see an experiment come to a definitive end with a precision measurement,' said Regina Rameika, the U.S. Department of Energy's Associate Director for the Office of High Energy Physics. This long-awaited result is a tremendous achievement of precision and will remain the world's most precise measurement of the muon magnetic anomaly for many years to come. Despite recent challenges with the theoretical predictions that reduce evidence of new physics from muon g-2, this result provides a stringent benchmark for proposed extensions of the Standard Model of particle physics. 'This is a very exciting moment because we not only achieved our goals but exceeded them, which is not very easy for these precision measurements,' said Peter Winter, a physicist at Argonne National Laboratory and co-spokesperson for the Muon g-2 collaboration. 'With the support of the funding agencies and the host lab, Fermilab, it has been very successful overall, as we reached or surpassed pretty much all the items that we were aiming for.' 'For over a century, g-2 has been teaching us a lot about the nature of nature,' said Lawrence Gibbons, professor at Cornell University and analysis co-coordinator for this result. 'It's exciting to add a precise measurement that I think will stand for a long time.' The Muon g-2 (pronounced 'gee minus two') experiment looks at the wobble of a fundamental particle called the muon. Muons are similar to electrons but about 200 times more massive; like electrons, muons have a quantum mechanical property called spin that can be interpreted as a tiny internal magnet. In the presence of an external magnetic field, the internal magnet will wobble — or precess — like the axis of a spinning top. The precession speed in a magnetic field depends on properties of the muon described by a number called the g-factor. Theoretical physicists calculate the g-factor based on the current knowledge of how the universe works at a fundamental level, which is contained in the Standard Model of particle physics. Nearly 100 years ago, the value of g was predicted to be 2. But experimental measurements soon showed g to be slightly different from 2 by a quantity known as the magnetic anomaly of the muon, aμ, calculated with (g-2)/2. The Muon g-2 experiment gets its name from this relation. The muon magnetic anomaly encodes the effects of all Standard Model particles, and theoretical physicists can calculate these contributions to an incredible precision. But previous measurements taken at Brookhaven National Laboratory in the late 1990s and early 2000s showed a possible discrepancy with the theoretical calculation at that time. When experiment doesn't align with theory, it could indicate new physics. Specifically, physicists wondered if this discrepancy could be caused by as-yet undiscovered particles pulling at the muon's precession. So physicists decided to upgrade the Muon g-2 experiment to make a more precise measurement. In 2013, Brookhaven's magnetic storage ring was transported from Long Island, New York, to Fermilab in Batavia, Illinois. After years of significant upgrades and improvements, the Fermilab Muon g-2 experiment started up on May 31, 2017. In parallel, an international collaboration of theorists formed the Muon g-2 Theory Initiative to improve the theoretical calculation. In 2020, the Theory Initiative published an updated, more precise Standard Model value based on a technique that uses input data from other experiments. The discrepancy with the result from that technique continued to grow in 2021 when Fermilab announced its first experimental result, confirming the Brookhaven result with a slightly improved precision. At the same time, a new theoretical prediction came out based on a second technique that heavily relies on computational power. This new number was closer to the experimental measurement, narrowing the discrepancy. Recently, the Theory Initiative published a new prediction combining the results of several groups that used the new computational technique. This result remains closer to the experimental measurement, dampening the possibility of new physics. However, the theoretical effort will continue to work to understand the discrepancy between the data-driven and computational approaches. The latest experimental value of the magnetic moment of the muon from the Fermilab experiment is: aμ = (g-2)/2 (muon, experiment) = 0.001 165 920 705 +- 0.000 000 000 114(stat.) +- 0.000 000 000 091(syst.) This final measurement is based on the analysis of the last three years of data, taken between 2021 and 2023, combined with the previously published datasets. This more than tripled the size of the dataset used for their second result in 2023, and it enabled the collaboration to finally achieve their precision goal proposed in 2012. It also represents an analysis of the experiment's best-quality data. Toward the end of their second data-taking run, the Muon g-2 collaboration finished tweaks and enhancements to the experiment that improved the quality of the muon beam and reduced uncertainties. The Muon g-2 collaboration describes the result in a paper that they submitted today to Physical Review Letters. 'As it has been for decades, the magnetic moment of the muon continues to be a stringent benchmark of the Standard Model,' said Simon Corrodi, assistant physicist at Argonne National Laboratory and analysis co-coordinator. 'The new experimental result sheds new light on this fundamental theory and will set the benchmark for any new theoretical calculation to come.' A future experiment at the Japan Proton Accelerator Research Complex will likely make another measurement of the muon magnetic anomaly in the early 2030s, but, initially, they won't achieve the same precision as Fermilab. Meanwhile, the Theory Initiative will continue working to resolve the inconsistency between their two theoretical predictions. The Muon g-2 collaboration is made up of nearly 176 scientists from 34 institutions in seven countries. Marco Incagli, a physicist with the Italian National Institute for Nuclear Physics at Pisa and co-spokesperson for Muon g-2, emphasized that the internationality of the collaboration was key to the success of the experiment. Unusually, the scientists also represent a variety of physics areas. 'This experiment is quite peculiar because it has very different ingredients in it,' said Incagli. 'It is really done by a collaboration among communities that normally work on different experiments.' Unlike other high-energy physics experiments, Muon g-2 needed more than just high-energy physicists; the collaboration is also composed of accelerator physicists, atomic physicists and nuclear physicists. 'It was very valuable to see that, when we had all these different experts come together, we could solve items that probably one group could not have done alone,' said Incagli. While the experiment's main analysis has come to an end, there is more to be mined from the six years of Muon g-2 data. In the future, the collaboration will produce measurements of a property of the muon called the electric dipole moment as well as tests of a fundamental property of physical laws known as charge, parity, and time-reversal symmetry. 'It's a really beautiful experiment,' said Gibbons. 'The data that comes out is really exquisite. It's been a privilege to have access to this data and analyze it.' 'Of course, it's sad to end such an endeavor because it's been a large part of many of our collaborators' lives,' said Winter, who has been part of the collaboration since 2011. 'But we also want to move to the next physics that's out there, to do our best to advance the field in other areas. 'I think it will be a textbook experiment that will be a long-lasting reference for many future decades to come,' Winter added. Fermi National Accelerator Laboratory is America's premier national laboratory for particle physics and accelerator research. Fermi Forward Discovery Group manages Fermilab for the U.S. Department of Energy Office of Science. Visit Fermilab's website at and follow us on social media. Attachments Muon g-2 ring Results plot graph CONTACT: Tracy Marc Fermilab 2242907803 TRACYM@ in to access your portfolio
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20-Year Mystery of The Muon's Wiggle May Finally Be Solved
Physicists at Fermilab have made the most precise measurement ever of a long-disputed value – the magnetic 'wiggle' of an elementary particle known as a muon. In somewhat disappointing news, that measurement is in strong agreement with the Standard Model, meaning it probably isn't hiding any exotic new physics as some had hoped. A muon is similar to an electron, except it's about 207 times more massive. The way muons move in a magnetic field should theoretically be very predictable, summed up in what's called its gyromagnetic ratio, or g. In a simple world, the value of g should be a nice, neat 2 – but of course, that would be too easy. The muon's magnetic dance is something of an anomaly, and in the same way that pi is just a touch over 3, the muon's g-factor seemed to be very slightly over 2. How slightly? Just 0.001165920705, according to new results from Fermilab's Muon g-2 experiment. This measurement incorporates data collected over six years of particle accelerator experiments. The team says this final number is accurate to within 127 parts per billion. To put that level of precision into perspective, the researchers say if you measured the width of the US to that degree, you'd be able to tell if a single grain of sand was missing. But the really intriguing part of the research is the room it left for new forces or particles to explain the anomalous magnetic motion. A related project called the Muon g-2 Theory Initiative set out to check what the Standard Model predicted for this value. Incorporating a wider dataset than ever, their latest calculation comes out at 0.00116592033. That puts it extremely close to the value gained from experimental means, which leaves very little wiggle room for any cool, exotic physics to be at play. "The anomalous magnetic moment, or g–2, of the muon is important because it provides a sensitive test of the Standard Model of particle physics," says Regina Rameika, experimental physicist at the US Department of Energy's Office of High Energy Physics. "This is an exciting result and it is great to see an experiment come to a definitive end with a precision measurement." As a muon spins inside a magnetic field, its poles should essentially line up with the field. That turned out to not be the case – instead, it wobbles ever so slightly, like an unbalanced spinning top. And if this wobble was particularly extreme, it could mean the muon is being nudged by unseen, unknown particles. A vacuum isn't ever truly empty – thanks to quantum fluctuations, pairs of virtual particles are constantly popping into and out of existence. These brief interlopers to our reality can affect other nearby particles in various ways. Thanks to its relative heft, the muon is particularly sensitive to the influence of virtual particles. So by precisely measuring how much the muon wobbles beyond its expected range, physicists could calculate the properties of these mysterious virtual particles, potentially unlocking a new realm of physics beyond the Standard Model. Hypothetical explanations could include dark photons or supersymmetry. The g-factor of the muon has been a fascinating thorn in the side of physicists for decades. Clues that something was amiss came in 2001, when the first version of the Muon g-2 experiment revealed a wide discrepancy between theory and practice. Further experiments over the decades since led to increasingly precise measurements, while techniques to calculate the predictions of the Standard Model also improved at the same time. And yet, a mismatch remained. The current version of the Muon g-2 experiment was fired up in 2018, conducting a new run of experiments each year until 2023. Data from the first three runs were released in two batches, each seeming to point more and more towards new physics. This latest measurement incorporates data from the full six runs, which more than triples the dataset used for the last release. That data isn't just more plentiful, but higher quality too, taking advantage of improvements made to the equipment. Sadly for those hoping to add a few extra chapters to their physics textbooks, it seems that in this case everything is as it should be. That's not to say we know everything though – dark matter and even gravity don't fit into the Standard Model yet, so there's still plenty of holes left to plug. The research has been submitted to the journal Physical Review Letters and is available on preprint server arXiv. Sound of Earth's Flipping Magnetic Field Is an Unforgettable Horror World-First Study Reveals How Lightning Sparks Gamma-Ray Flashes The Universe Is 'Suspiciously' Like a Computer Simulation, Physicist Says
