193 research outputs found
ScannerS: Constraining the phase diagram of a complex scalar singlet at the LHC
We present the first version of a new tool to scan the parameter space of
generic scalar potentials, ScannerS. The main goal of ScannerS is to help
distinguish between different patterns of symmetry breaking for each scalar
potential. In this work we use it to investigate the possibility of excluding
regions of the phase diagram of several versions of a complex singlet extension
of the Standard Model, with future LHC results. We find that if another scalar
is found, one can exclude a phase with a dark matter candidate in definite
regions of the parameter space, while predicting whether a third scalar to be
found must be lighter or heavier. The first version of the code is publicly
available and contains various generic core routines for tree level vacuum
stability analysis, as well as implementations of collider bounds, dark matter
constraints, electroweak precision constraints and tree level unitarity.Comment: 24 pages, 4 figures, 3 tables. Project development webpage -
http://gravitation.web.ua.pt/Scanner
NLO electroweak corrections in general scalar singlet models
If no new physics signals are found, in the coming years, at the Large Hadron
Collider Run-2, an increase in precision of the Higgs couplings measurements
will shift the dicussion to the effects of higher order corrections. In Beyond
the Standard Model (BSM) theories this may become the only tool to probe new
physics. Extensions of the Standard Model (SM) with several scalar singlets may
address several of its problems, namely to explain dark matter, the
matter-antimatter asymmetry, or to improve the stability of the SM up to the
Planck scale. In this work we propose a general framework to calculate one
loop-corrections in BSM models with an arbitrary number of scalar singlets. We
then apply our method to a real and to a complex scalar singlet models. We
assess the importance of the one-loop radiative corrections first by computing
them for a tree level mixing sum constraint, and then for the main Higgs
production process . We conclude that, for the currently allowed
parameter space of these models, the corrections can be at most a few percent.
Notably, a non-zero correction can survive when dark matter is present, in the
SM-like limit of the Higgs couplings to other SM particles.Comment: 35 pages, 3 figure
Wrong sign and symmetric limits and non-decoupling in 2HDMs
We analyse the possibility that, in two Higgs doublet models, one or more of
the Higgs couplings to fermions or to gauge bosons change sign, relative to the
respective Higgs Standard Model couplings. Possible sign changes in the
coupling of a neutral scalar to charged ones are also discussed. These
\textit{wrong signs} can have important physical consequences, manifesting
themselves in Higgs production via gluon fusion or Higgs decay into two gluons
or into two photons. We consider all possible wrong sign scenarios, and also
the \textit{symmetric limit}, in all possible Yukawa implementations of the two
Higgs doublet model, in two different possibilities: the observed Higgs boson
is the lightest CP-even scalar, or the heaviest one. We also analyse thoroughly
the impact of the currently available LHC data on such scenarios. With all 8
TeV data analysed, all wrong sign scenarios are allowed in all Yukawa types,
even at the 1 level. However, we will show that B-physics constraints
are crucial in excluding the possibility of wrong sign scenarios in the case
where is below 1. We will also discuss the future prospects for
probing the wrong sign scenarios at the next LHC run. Finally we will present a
scenario where the alignment limit could be excluded due to non-decoupling in
the case where the heavy CP-even Higgs is the one discovered at the LHC.Comment: 20 pages, 15 figure
Hawking radiation for a Proca field in D-dimensions
We study the wave equation of a massive vector boson in the background of a
D-dimensional Schwarzschild black hole. The mass term introduces a coupling
between two physical degrees of freedom of the field, and we solve the
resulting system of ODEs numerically, without decoupling. We show how to define
decoupled transmission factors from an S-matrix and compute them for various
modes, masses and space-time dimensions. The mass term lifts the degeneracy
between transverse modes, in D=4, and excites the longitudinal modes, in
particular the s-wave. Moreover, it increases the contribution of waves with
larger angular momentum, which can be dominant at intermediate energies. The
transmission factors are then used to obtain the Hawking fluxes in this
channel. Our results alert for the importance of modelling the longitudinal
modes correctly, instead of treating them as decoupled scalars as in current
black hole event generators; thus they can be used to improve such generators
for phenomenological studies of TeV gravity scenarios.Comment: 21 pages, 3 figure
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