Flavor-changing neutral current

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Above: Highly suppressed tau decay via flavor-changing neutral current at one-loop order in the Standard Model.
Below: Beyond the Standard Model tau decay via flavor-changing neutral current mediated by a new S boson.
An example of a hypothetical (i.e., not yet observed) flavor-changing neutral current process in the Minimal Supersymmetric Standard Model. A strange quark emits a bino, turning into a sdown-type squark, which then emits a Z boson and reabsorbs the bino, turning into a down quark. If the MSSM squark masses are flavor-violating, such a process can occur.

In particle physics, flavor-changing neutral currents or flavour-changing neutral currents (FCNCs) are hypothetical interactions that change the flavor of a fermion without altering its electric charge.

Details[edit]

If they occur in nature (as reflected by Lagrangian interaction terms), these processes may induce phenomena that have not yet been observed in experiment. Flavor-changing neutral currents may occur in the Standard Model beyond the tree level, but they are highly suppressed by the GIM mechanism. Several collaborations have searched for FCNC.[1][2][3] The Tevatron CDF experiment observed evidence of FCNC in the decay of the strange B-meson to phi mesons in 2005.[4]

FCNCs are generically predicted by theories that attempt to go beyond the Standard Model, such as the models of supersymmetry or technicolor. Their suppression is necessary for an agreement with observations, making FCNCs important constraints on model-building.

Example[edit]

Consider a toy model in which an undiscovered boson S may couple both to the electron as well as the tau (
τ
)
via the term

Since the electron and the tau have equal charges, the electric charge of S clearly must vanish to respect the conservation of electric charge. A Feynman diagram with S as the intermediate particle is able to convert a tau into an electron (plus some neutral decay products of the S).

The MEG experiment[5] at the Paul Scherrer Institute near Zürich will search for a similar process, in which an antimuon decays to a photon and an antielectron (a positron). In the Standard Model, such a process proceeds only by emission and re-absorption of a charged
W+
, which changes the
μ+
into a neutrino on emission and then a positron on re-absorption, and finally emits a photon that carries away any difference in energy, spin, and momentum.

In most cases of interest, the boson involved is not a new boson S but the conventional
Z0
 boson
itself.[6] This can occur if the coupling to weak neutral currents is (slightly) non-universal. The dominant universal coupling to the Z boson does not change flavor, but sub-dominant non-universal contributions can.

FCNCs involving the
Z
 boson for the down-type quarks at zero momentum transfer are usually parameterized by the effective action term

This particular example of FCNC is often studied the most because we have some fairly strong constraints coming from the decay of
B0
 mesons
in Belle and BaBar. The off-diagonal entries of U parameterizes the FCNCs and current constraints restrict them to be less than one part in a thousand for |Ubs|. The contribution coming from the one-loop Standard Model corrections are actually dominant, but the experiments are precise enough to measure slight deviations from the Standard Model prediction.

Experiments tend to focus on flavor-changing neutral currents as opposed to charged currents, because the weak neutral current (
Z0
 boson) does not change flavor in the Standard Model proper at the tree level whereas the weak charged currents (
W±
 bosons) do. New physics in charged current events would be swamped by more numerous
W±
 boson interactions; new physics in the neutral current would not be masked by a large effect due to ordinary Standard Model physics.

See also[edit]

References[edit]

  1. ^ Anderson, S.; et al. (CLEO Collaboration) (2001). "Improved Upper Limits on the Flavor-Changing Neutral Current Decays B→Kℓ+

    and B→K*(892)ℓ+

    ". Physical Review Letters. 87 (18): 181803. arXiv:hep-ex/0106060. Bibcode:2001PhRvL..87r1803A. doi:10.1103/PhysRevLett.87.181803. S2CID 119477202.
  2. ^ CMS Collaboration (2022). "Search for Flavor-Changing Neutral Current Interactions of the Top Quark and Higgs Boson in Final States with Two Photons in Proton-Proton Collisions at s=13 TeV". Physical Review Letters. 129 (3): 032001. arXiv:2111.02219. doi:10.1103/PhysRevLett.129.032001. PMID 35905365.
  3. ^ "Hunting for anomalous interactions between the Higgs bosons and the top quarks | CMS Experiment". cms.cern. Retrieved 2021-12-24.
  4. ^ Acosta, D.; et al. (CDF Collaboration) (2005-07-15). "First Evidence for B0
    s
    →φφ Decay and Measurements of Branching Ratio and A
    CP
    for B+
    →φK+
    ". Physical Review Letters. 95 (3): 031801. arXiv:hep-ex/0502044. Bibcode:2005PhRvL..95c1801A. doi:10.1103/PhysRevLett.95.031801. PMID 16090735. S2CID 40241424.
  5. ^ "MEG experiment website".
  6. ^ FCNCs involving the photon cannot occur at zero momentum transfers, because of the unbroken electromagnetic gauge symmetry; as such, FCNCs involving the photon at a non-zero momentum transfer are relatively suppressed compared to FCNCs involving the
    Z
     boson.