Abstract
Abstract
Baryon number violation is our most sensitive probe of physics beyond the Standard Model, especially through the study of nucleon decays. Angular momentum conservation requires a lepton in the final state of such decays, kinematically restricted to electrons, muons, or neutrinos. We show that operators involving taus, which are at first sight too heavy to play a role in nucleon decays, still lead to clean nucleon decay channels with tau neutrinos. While many of them are already constrained from existing two-body searches such as p → π+ν, other operators induce many-body decays such as $$ p\to {\eta \pi}^{+}{\overline{\nu}}_{\tau } $$
p
→
ηπ
+
ν
¯
τ
and n → K+π−ντ that have never been searched for.
Publisher
Springer Science and Business Media LLC
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