The difference between predictions and observations of the magnetic properties of muons suggests a mystery for the Standard Model.
Modern physics is in an unsettling state. The Standard Model
is the name of the best theory ever devised to explain subatomic physics, and
it is wildly successful, with many measurements agreeing extremely well with
predictions. However, there remain some very big mysteries. For instance,
current theory cannot explain why antimatter isn’t observed in nature, nor can
it provide an explanation for dark matter or dark energy. So, it is clear that
the Standard Model is incomplete.
Despite decades of experimentation using large particle
accelerators, researchers have not found any discrepancy that points them in a
promising direction. However, particle accelerators are not the only way to
study the laws of nature. Other scientists use tabletop experiments to measure
fundamental constants extremely precisely, hoping to find disagreements between
predictions and measurements that will allow scientists to develop better
theories.
Measuring the electron’s magnetic moment
Now, a new measurement of the magnetic properties of the
humble electron has achieved staggering precision and has agreed well with
prediction, while simultaneously confusing the world’s physics research
community.
Like many subatomic particles, the electron has an electric
charge and acts like a tiny magnet. The theory of quantum mechanics developed
in the 1920s predicted the strength of the magnet of a single electron (known
as the magnetic moment) to decent precision. However, in 1947, measurements and
calculations found that the early predictions were slightly inaccurate. Improved calculations that included the
effects of all known subatomic particles shifted the value of the magnetic
properties of the electron by 0.1%.
While this is a tiny effect, it gives researchers a way to
look for the existence of new particles — that is, particles not currently
accounted for in the Standard Model. If more particles exist, the calculation
once again will change slightly.
Accordingly, researchers have embarked on a program spanning
decades to achieve an ever more precise measurement of the magnetic properties
of the electron. In the fall of 2022, researchers announced a result in which
the measurement and prediction agree with a staggering twelve digits of
accuracy. The new measurement claims to be correct to a factor of 1.3 out of 10
trillion.
The fact that prediction and measurement agree so incredibly
well is a triumph of both experimental and theoretical prowess and provides a
solid argument that this measurement is not sensitive to effects beyond the
Standard Model. In other words, there’s no “new physics” to see here.
A muon mystery
But this isn’t the whole story. The electron is not the only
subatomic particle that acts like a tiny magnet and for which the strength of
the magnet depends on all the subatomic particles known to scientists.
The muon is a cousin of the electron. Like the electron, it
has the same charge and acts like a magnet. But the muon is about 200 times
heavier than the electron and is unstable, as it decays in 2.2 microseconds. As
with the electron, the muon has magnetic properties that are 0.1% larger than
predicted by 1920s quantum mechanics.
Scientists can measure and calculate the magnetic moment of
the muon, although with less precision than the electron: The reported
uncertainty is about 4.6 parts per ten million. (Full disclosure: The
measurement of the muon’s magnetic moment was performed at Fermi National
Accelerator Laboratory, where I am a senior scientist.)
For the muon, the experimentally measured and theoretically
calculated value of its magnetic properties do not quite agree. When two
numbers disagree, the reason could be that one or both are inaccurate. Or it
could be a statistical fluke (like flipping heads ten times in a row with a
fair coin). Most excitingly, it could be pointing to an unknown phenomenon —
“new physics.”
A proper statistical analysis shows that we would need to
run the experiment about 40,000 times to see the observed disagreement just by
chance. Since this is highly improbable, scientists are seriously starting to
consider the possibility that the discrepancy seen in muon measurements is a
hint of undiscovered physics.
New physics?
It is worth noting that both the measurement and prediction
of the muon’s magnetic moment are still in flux, and updates are expected soon.
But there is reason to be (at least a little) excited.
The new measurement of the electron’s magnetic moment is a
bit confounding. It is 3,100 times more precise than the same measurement for
the muon, and the electron’s measurement agrees quite well with the Standard
Model. Why would the measurement for the muon be less precise and disagree with
the prediction of the Standard Model? It’s as if the electron and muon are
telling us different stories.
Perhaps further investigation into the fundamental nature of electrons and muons will provide crucial clues to the undiscovered laws of nature.
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