{"id":14767,"date":"2025-06-05T22:00:00","date_gmt":"2025-06-05T22:00:00","guid":{"rendered":"https:\/\/modernsciences.org\/staging\/4414\/?p=14767"},"modified":"2025-06-04T05:34:37","modified_gmt":"2025-06-04T05:34:37","slug":"muon-g-2-muon-magnetism-antimatter-dark-matter-fermilab-physics-mystery-june-2025","status":"publish","type":"post","link":"https:\/\/modernsciences.org\/staging\/4414\/muon-g-2-muon-magnetism-antimatter-dark-matter-fermilab-physics-mystery-june-2025\/","title":{"rendered":"How physicists used antimatter, supercomputers and giant magnets to solve a\u00a020-year-old\u00a0mystery"},"content":{"rendered":"\n

<\/p>\n\n\n\n\n

\n
\n \n
\n \n Cindy Arnold, Fermilab<\/a><\/span>\n <\/figcaption>\n <\/figure>\n\n Finn Stokes<\/a>, University of Adelaide<\/a><\/em><\/span>\n\n

Physicists are always searching for new theories to improve our understanding of the universe and resolve big unanswered questions.<\/p>\n\n

But there\u2019s a problem. How do you search for undiscovered forces or particles when you don\u2019t know what they look like?<\/p>\n\n

Take dark matter. We see signs of this mysterious cosmic phenomenon throughout the universe, but what could it possibly be made of? Whatever it is, we\u2019re going to need new physics to understand what\u2019s going on.<\/p>\n\n

Thanks to a new experimental result<\/a> published today, and the new theoretical calculations<\/a> that accompany it, we may now have an idea what this new physics should look like \u2013 and maybe even some clues about dark matter.<\/p>\n\n

Meet the muon<\/h2>\n\n

For 20 years, one of the most promising signs of new physics has been\na tiny inconsistency in the magnetism of a particle called the muon. The muon is a lot like an electron but is much heavier. <\/p>\n\n

Muons are produced when cosmic rays \u2013 high-energy particles from space \u2013 hit Earth\u2019s atmosphere<\/a>. Roughly 50 of these muons pass through your body every second. <\/p>\n\n

Muons travel through solid objects much better than x-rays, so they are useful for finding out what is inside large structures. For example, they have been used to look for hidden chambers in Egyptian<\/a> and Mexican<\/a> pyramids; to study magma chambers inside volcanoes<\/a> to predict volcanic eruptions; and to safely see inside the Fukushima nuclear reactor<\/a> after it melted down.<\/p>\n\n

A tiny crack in physics?<\/h2>\n\n

In 2006, researchers at Brookhaven National Laboratory<\/a> in the United States measured the strength of the muon\u2019s magnetism incredibly precisely<\/a>. <\/p>\n\n

Their measurement was accurate to roughly six parts in ten billion. This is equivalent to measuring the mass of a loaded freight train to ten grams. This was compared to a similarly impressive theoretical calculation. <\/p>\n\n

When researchers compared the two numbers, they found a tiny but significant difference, indicating a mismatch between theory and experiment. Had they finally found the new physics they\u2019d been looking for?<\/p>\n\n

A better experiment<\/h2>\n\n

To find a definitive answer, the international scientific community started a 20-year program to increase the precision of both results.<\/p>\n\n

The huge electromagnet from the original experiment was loaded onto a barge and shipped down the east coast of the US and then up the Mississippi River to Chicago. There, it was installed at Fermilab<\/a> for a completely overhauled experiment. <\/p>\n\n

\n \"Photo<\/a>\n
\n The giant ring of magnets used to study the muon\u2019s magnetism was shipped from New York to Chicago in 2013.<\/span>\n Reidar Hahn\/ Fermilab<\/a><\/span>\n <\/figcaption>\n <\/figure>\n\n

Just this morning, researchers announced they had finished that experiment. Their final result<\/a> for the strength of the muon\u2019s magnetism is 4.4 times more precise, at one-and-a-half parts in ten billion.<\/p>\n\n

And better calculations<\/h2>\n\n

To keep up, theorists had to make sweeping improvements too. They formed the Muon g-2 Theory Initiative<\/a>, an international collaboration of more than 100 scientists, dedicated to making an accurate theoretical prediction. <\/p>\n\n

They computed the contributions to the muon\u2019s magnetism from more than 10,000 factors. They even included a particle called the Higgs boson, which was only discovered in 2012.<\/p>\n\n

But there was one last sticking point: the strong nuclear force, one of the universe\u2019s four fundamental forces. In particular, computing the largest contribution to the result from the strong nuclear force was no easy feat.<\/p>\n\n

Antimatter vs supercomputers<\/h2>\n\n

It was not possible to compute this contribution in the same way as the others, so we needed a different approach. <\/p>\n\n

In 2020, the Theory Initiative turned to collisions between electrons and their antimatter counterparts: positrons. Measurements of these electron\u2013positron collisions provided the missing values we needed. <\/p>\n\n

Put together with all the other parts, this gave a result<\/a> that strongly disagreed with the latest experimental measurement. The disagreement was almost strong enough to announce the discovery of new physics.<\/p>\n\n

\n \"Photo<\/a>\n
\n Simulations carried out with the Hawk supercomputer at the High-Performance Computing Center Stuttgart resolved the discrepancy between calculations and experiment.<\/span>\n Marijan Murat\/picture alliance via Getty Images<\/span><\/span>\n <\/figcaption>\n <\/figure>\n\n

At the same time, I was exploring a different approach. Along with my colleagues in the Budapest-Marseille-Wuppertal collaboration, we performed a supercomputer simulation of this strong contribution<\/a>. <\/p>\n\n

Our result eliminated the tension between theory and experiment. However, now we had a new tension: between our simulation and the electron\u2013positron results which had withstood 20 years of scrutiny. How could those 20-year-old results be wrong?<\/p>\n\n

Hints of new physics disappear<\/h2>\n\n

Since then, two other groups have produced full simulations that agree with ours, and many more have validated parts of our result. We have also produced a new, overhauled simulation that almost doubles our precision<\/a> (released as a preprint, which has not yet been peer-reviewed or published in a scientific journal).<\/p>\n\n

To ensure these new simulations weren\u2019t affected by any preconceptions, they were performed \u201cblind\u201d. The simulation data was multiplied by an unknown number before being analysed, so we didn\u2019t know what a \u201cgood\u201d or \u201cbad\u201d result would be.<\/p>\n\n

We then held a nerve-wracking and exciting meeting. The blinding factor was revealed, and we found out the results of years of work all at once. After all this, our latest result agrees even better with the experimental measurement of the muon\u2019s magnetism.<\/p>\n\n

But others emerge<\/h2>\n\n

The Muon g-2 Theory Initiative has moved to using the simulation results instead of the electron-positron data in its official prediction<\/a>, and the hint of new physics seems to be gone.<\/p>\n\n

Except \u2026 why does the electron\u2013positron data disagree? Physicists around the globe have studied this question extensively, and one exciting suggestion<\/a> is a hypothetical particle called a \u201cdark photon\u201d. <\/p>\n\n

Not only could the dark photon explain the difference between the latest muon results and the electron\u2013positron experiments, but (if it exists) it could also explain how dark matter relates to ordinary matter.\"The<\/p>\n\n

Finn Stokes<\/a>, Ramsay Fellow in Physics, University of Adelaide<\/a><\/em><\/span><\/p>\n\n

This article is republished from The Conversation<\/a> under a Creative Commons license. Read the original article<\/a>.<\/p>\n<\/div>\n\n","protected":false},"excerpt":{"rendered":"Cindy Arnold, Fermilab Finn Stokes, University of Adelaide Physicists are always searching for new theories to improve our…\n","protected":false},"author":1225,"featured_media":14769,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"nf_dc_page":"","fifu_image_url":"https:\/\/upload.wikimedia.org\/wikipedia\/commons\/a\/a2\/Dark_Matter_%28123450201%29.jpeg","fifu_image_alt":"","footnotes":""},"categories":[16],"tags":[11589,11606,11597,11605,11601,373,287,11604,11587,11590,11596,11594,11607,562,11600,11595,3333,11591,11593,11588,11602,4037,628,11592,537,10369,11598,1388,11599,11603],"class_list":{"0":"post-14767","1":"post","2":"type-post","3":"status-publish","4":"format-standard","5":"has-post-thumbnail","7":"category-tech","8":"tag-antimatter-collisions","9":"tag-blind-analysis","10":"tag-budapest-marseille-wuppertal-collaboration","11":"tag-collider-data","12":"tag-computational-physics","13":"tag-cosmic-rays","14":"tag-dark-matter","15":"tag-dark-matter-interaction","16":"tag-dark-photon","17":"tag-electron-positron-collisions","18":"tag-experimental-physics","19":"tag-fermilab-experiment","20":"tag-fundamental-forces","21":"tag-higgs-boson","22":"tag-high-precision-measurement","23":"tag-lattice-qcd","24":"tag-magnetic-moment","25":"tag-muon-anomaly","26":"tag-muon-g-2","27":"tag-muon-magnetism","28":"tag-muon-vs-electron","29":"tag-new-physics","30":"tag-particle-physics","31":"tag-quantum-field-theory","32":"tag-standard-model","33":"tag-strong-nuclear-force","34":"tag-supercomputer-simulation","35":"tag-theoretical-physics","36":"tag-theory-initiative","37":"tag-undiscovered-particles","38":"cs-entry","39":"cs-video-wrap"},"aioseo_notices":[],"_links":{"self":[{"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/posts\/14767","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/users\/1225"}],"replies":[{"embeddable":true,"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/comments?post=14767"}],"version-history":[{"count":1,"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/posts\/14767\/revisions"}],"predecessor-version":[{"id":14768,"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/posts\/14767\/revisions\/14768"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/media\/14769"}],"wp:attachment":[{"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/media?parent=14767"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/categories?post=14767"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/modernsciences.org\/staging\/4414\/wp-json\/wp\/v2\/tags?post=14767"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}