Constraints on 
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 operators from 
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 flavor-changing meson decays

Self Cite

Upcoming searches for lepton flavour change (LFV) aim to probe New Physics (NP) scales up to ΛNP ∼ 104 TeV, implying that they will be sensitive to NP at lower scales that is suppressed by loops or small couplings. We suppose that the NP responsable for LFV is beyond the reach of the LHC and can be parametrised in Effective Field Theory, introduce a small power-counting parameter λ (à la Cabibbo-Wolfenstein), and assess whether the existing dimension six operator basis and one-loop RGEs provide a good approximation for LFV. We find that μ ↔ e observables can be sensitive to a few dozen dimension eight operators, and to some effects of two-loop anomalous dimensions, for ΛNP ≲ 20 − 100 TeV. We also explore the effect of some simplifying assumptions in the one-loop RGEs, such as neglecting flavour-changing effects.

Section: Examplesmentioning

confidence: 99%

What is Leading Order for LFV in SMEFT?

Ardu

Davidson

2021

Self Cite

“…The contribution of dimension-6 operators to CLFV observables arises at O(Λ −4 ), which is the leading order in this case because the SM contributions are absent. The resulting constraints on lepton-flavor off-diagonal SMEFT operators are typically very severe [65][66][67][68]. Using the analytical formula for the µ → e conversion rate in Ref.…”

Section: Charged-lepton-flavor Violationmentioning

confidence: 99%

Reactor neutrino oscillations as constraints on effective field theory

Falkowski

González–Alonso

Tabrizi

2019

We study constraints on the Standard Model Effective Field Theory (SMEFT) from neutrino oscillations in short-baseline reactor experiments. We calculate the survival probability of reactor antineutrinos at the leading order in the SMEFT expansion, that is including linear effects of dimension-6 operators. It is shown that, at this order, reactor experiments alone cannot probe charged-current contact interactions between leptons and quarks that are of the (pseudo)vector (V±A) or pseudo-scalar type. We also note that flavor-diagonal (pseudo)vector coefficients do not have observable effects in oscillation experiments. In this we reach novel or different conclusions than prior analyses of non-standard neutrino interactions. On the other hand, reactor experiments offer a unique opportunity to probe tensor and scalar SMEFT operators that are offdiagonal in the lepton-flavor space. We derive constraints on the corresponding SMEFT parameters using the most recent data from the Daya Bay and RENO experiments.

“…Detailed analyses of these RGEs have been presented in refs. [10,11,13,19,[42][43][44]. We evaluate the bounds from µ → eγ and µ → e conversion by turning on single operators at a time at the scale µ = M W .…”

Section: Lepton-flavor-violating Processesmentioning

confidence: 99%

“…The constraints of lepton-flavor-violating processes such as µ → eγ and µ → 3e on the Wilson coefficients of both SMEFT and LEFT have attracted a lot of attention in connection with perturbative effects [8][9][10][11], while the non-perturbative effects due to leptonflavor-violating quark operators have been studied mainly in reactions involving hadrons as external states [12][13][14][15][16][17][18][19]. In our analysis, we consider non-perturbative contributions to µ → eγ, a decay that has no strongly interacting external particles.…”

Section: Introductionmentioning

confidence: 99%

Non-perturbative effects in μ → eγ

Dekens

Jenkins

Manohar

et al. 2019

We compute the non-perturbative contribution of semileptonic tensor operators (qσ µν q)(¯ σ µν) to the purely leptonic process µ → eγ and to the electric and magnetic dipole moments of charged leptons by matching onto chiral perturbation theory at low energies. This matching procedure has been used extensively to study semileptonic and leptonic weak decays of hadrons. In this paper, we apply it to observables that contain no strongly interacting external particles. The non-perturbative contribution to µ → e processes is used to extract the best current bound on lepton-flavor-violating semileptonic tensor operators, Λ BSM 450 TeV. We briefly discuss how the same method applies to dark-matter interactions.