μ to e in R -symmetric supersymmetry

159

R-symmetry is a fundamental symmetry which can solve the SUSY flavor problem and relax the search limits on SUSY masses. Here we provide a complete next-toleading order computation and discussion of the lightest Higgs boson mass, the W boson mass and muon decay in the minimal R-symmetric SUSY model (MRSSM). This model contains non-MSSM particles including a Higgs triplet, Dirac gauginos and higgsinos, and leads to significant new tree-level and one-loop contributions to these observables. We show that the model can accommodate the measured values of the observables for interesting regions of parameter space with stop masses of order 1 TeV in spite of the absence of stop mixing. We characterize these regions and provide typical benchmark points, which are also checked against further experimental constraints. A detailed exposition of the model, its mass matrices and its Feynman rules relevant for computations in this paper is also provided.

Section: Jhep12(2014)124supporting

confidence: 59%

Higgs boson mass and electroweak observables in the MRSSM

Diessner

Kalinowski

Kotlarski

et al. 2014

159

“…This is a consequence of the fact that most flavor violating observables turn out to be proportional to terms which break R-symmetry, and are hence suppressed [11][12][13]. Therefore, a significant amount of flavor mixing is possible and quite generic.…”

Section: Jhep01(2014)115mentioning

confidence: 99%

Mixing stops at the LHC

Agrawal

Frugiuele

2014

Abstract:We study the phenomenology of a light stop NLSP in the presence of large mixing with either the first or the second generation. R-symmetric models provide a prime setting for this scenario, but our discussion also applies to the MSSM when a significant amount of mixing can be accommodated. In our framework the dominant stop decay is through the flavor violating mode into a light jet and the LSP in an extended region of parameter space. There are currently no limits from ATLAS and CMS in this region. We emulate shape-based hadronic SUSY searches for this topology, and find that they have potential sensitivity. If the extension of these analyses to this region is robust, we find that these searches can set strong exclusion limits on light stops. If not, then the flavor violating decay mode is challenging and may represent a blind spot in stop searches even at 13 TeV. Thus, an experimental investigation of this scenario is well motivated.

“…In addition, the LHC phenomenology is non standard, both due to the Dirac nature of the gluino [9][10][11][12] and to the presence of additional particles that can be rather easily detected [13]. Moreover, the Flavor Problem is also softened, since unsuppressed flavor changing terms are now allowed for sufficiently heavy gaugino Dirac masses [4,14].…”

Section: Jhep05(2012)100mentioning

confidence: 99%

Fitting neutrino physics with a U(1) R lepton number

Bertuzzo

Frugiuele

2012

We study neutrino physics in the context of a supersymmetric model where a continuous R-symmetry is identified with the total Lepton Number and one sneutrino can thus play the role of the down type Higgs. We show that R-breaking effects communicated to the visible sector by Anomaly Mediation can reproduce neutrino masses and mixing solely via radiative contributions, without requiring any additional degree of freedom. In particular, a relatively large reactor angle (as recently observed by the Daya Bay collaboration) can be accommodated in ample regions of the parameter space. On the contrary, if the R-breaking is communicated to the visible sector by gravitational effects at the Planck scale, additional particles are necessary to accommodate neutrino data.