Muon g–2: New physics governing the laws of nature
Part of: GS Prelims and GS – III – Sci & tech
In news
- Newly published results of an international experiment hint at the possibility of new physics governing the laws of nature.
- The experiment, called Muon g–2 (g minus two), was conducted at the US Department of Energy’s Fermi National Accelerator Laboratory (Fermilab).
Key takeaways
- The experiment studied a subatomic particle called the muon.
- Its results do not match the predictions of the Standard Model, on which all particle physics is based.
- The results instead reconfirm a discrepancy that had been detected in an experiment 20 years ago.
- Concluded in 2001, the Brookhaven experiment came up with results that did not identically match predictions by the Standard Model.
- The Muon g–2 experiment measured this quantity with greater accuracy.
What is the Standard Model?
- The Standard Model is a rigorous theory that predicts the behaviour of the building blocks of the universe.
- It lays out the rules for six types of quarks, six leptons, the Higgs boson, three fundamental forces, and how the subatomic particles behave under the influence of electromagnetic forces.
- The muon is one of the leptons.
- It is similar to the electron, but 200 times larger, and much more unstable, surviving for a fraction of a second.
What quantity was measured?
- g–factor was measured.
- It is a measure that derives from the magnetic properties of the muon.
- The rate at which the muon wobbles is described by the g-factor.
- This value is known to be close to 2, so scientists measure the deviation from 2. Hence the name g–2.
- The new experimental results (combined from the Brookhaven and Fermilab results) announced are:
- g-factor: 00233184122
- anomalous magnetic moment: 00116592061
: New physics governing the laws of nature
Part of: GS Prelims and GS – III – Sci & tech
In news
- Newly published results of an international experiment hint at the possibility of new physics governing the laws of nature.
- The experiment, called Muon g–2 (g minus two), was conducted at the US Department of Energy’s Fermi National Accelerator Laboratory (Fermilab).
Key takeaways
- The experiment studied a subatomic particle called the muon.
- Its results do not match the predictions of the Standard Model, on which all particle physics is based.
- The results instead reconfirm a discrepancy that had been detected in an experiment 20 years ago.
- Concluded in 2001, the Brookhaven experiment came up with results that did not identically match predictions by the Standard Model.
- The Muon g–2 experiment measured this quantity with greater accuracy.
What is the Standard Model?
- The Standard Model is a rigorous theory that predicts the behaviour of the building blocks of the universe.
- It lays out the rules for six types of quarks, six leptons, the Higgs boson, three fundamental forces, and how the subatomic particles behave under the influence of electromagnetic forces.
- The muon is one of the leptons.
- It is similar to the electron, but 200 times larger, and much more unstable, surviving for a fraction of a second.
What quantity was measured?
- g–factor was measured.
- It is a measure that derives from the magnetic properties of the muon.
- The rate at which the muon wobbles is described by the g-factor.
- This value is known to be close to 2, so scientists measure the deviation from 2. Hence the name g–2.
- The new experimental results (combined from the Brookhaven and Fermilab results) announced are:
- g-factor: 00233184122
- anomalous magnetic moment: 00116592061
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