However, a nonzero electron EDM indicates P and CP breaking; in the standard model it’s generated through loop effects from the CP violation in the CKM matrix, making it very very small (1e-38 e•cm).
The experimental results are that it’s zero with a precision of ~1e-28 e•cm. So, there’s TEN orders of magnitude between experiment and theory—-that makes it not a particularly silly thing to measure, but a particularly appealing experimental target: lots of models of new physics predict something substantially larger than 1e-38, and the small value in the standard model makes a nonzero measurement an obvious signal.
Contrast the muon g-2 measurements, for example, where a new lattice QCD calculation of standard-model effects claims to adjust the prediction in the 10th decimal, reducing the tension to 1.5 sigma. If an electron EDM is found anywhere in the next… 8 or 9 orders of magnitude, it’d be an inarguable sign of new physics.
That is exactly the point I am making with my (facetious) comment. We measure it because a mismatch from the very much exected result would be monumentally important, even if improbable.
https://en.wikipedia.org/wiki/Electron_electric_dipole_momen...
However, a nonzero electron EDM indicates P and CP breaking; in the standard model it’s generated through loop effects from the CP violation in the CKM matrix, making it very very small (1e-38 e•cm).
The experimental results are that it’s zero with a precision of ~1e-28 e•cm. So, there’s TEN orders of magnitude between experiment and theory—-that makes it not a particularly silly thing to measure, but a particularly appealing experimental target: lots of models of new physics predict something substantially larger than 1e-38, and the small value in the standard model makes a nonzero measurement an obvious signal.
Contrast the muon g-2 measurements, for example, where a new lattice QCD calculation of standard-model effects claims to adjust the prediction in the 10th decimal, reducing the tension to 1.5 sigma. If an electron EDM is found anywhere in the next… 8 or 9 orders of magnitude, it’d be an inarguable sign of new physics.