"L=R" - $U(1)_R$ as the Origin of Leptonic 'RPV'

TL;DR

This paper explores supersymmetric models with a $U(1)_R$ symmetry that naturally lead to leptonic R-parity violation, offering distinctive phenomenological signatures and connections to neutrino physics, while remaining consistent with experimental bounds.

Contribution

It introduces a class of $U(1)_R$ symmetric supersymmetric models where lepton number is extended non-standardly, leading to novel RPV operators and rich phenomenology.

Findings

Models accommodate the observed Higgs mass with moderate fine-tuning.

Existence of heavy Dirac gauginos and relaxed squark bounds.

Distinctive signals like resonant slepton production and lepto-quark signatures.

Abstract

A classification of phenomenologically interesting supersymmetric extensions of the Standard-Model with a $U(1)_R$ symmetry is presented. Some of these are consistent with subsets of leptonic or baryonic "R-parity violating" (RPV) operators, thereby providing a natural motivation for them. We then focus on a particular class of models in which the $U(1)_R$ symmetry coincides with lepton number when restricted to the SM sector. In this case, the extension of lepton number to the superpartners is "non-standard", implying, in particular, the existence of the leptonic RPV operators $LLE^c$ and $LQD^c$, and a vacuum structure where one of the left-handed sneutrinos acquires a significant vacuum-expectation-value, while not being constrained by neutrino mass bounds. The model can be naturally consistent with bounds from electroweak precision measurements and flavor-changing processes. It can also easily accommodate the recently measured Higgs mass due to the existence of a scalar triplet that couples to the Higgs with an order one coupling, with only moderate fine-tuning. The phenomenology is rather rich and distinctive, with features such as heavy-but-natural Dirac gauginos, relaxed bounds on squarks, resonant slepton/sneutrino production, lepto-quark signals, as well as an interesting connection to neutrino physics arising from R-breaking. The broad qualitative features are discussed in this paper, with a more detailed phenomenological study carried out in a companion paper Frugiuele et al. (2012).