895 research outputs found
Lepton Flavor Violation, Neutralino Dark Matter and the Reach of the LHC
We revisit the phenomenology of the Constrained MSSM with right-handed
neutrinos (CMSSMRN). A supersymmetric seesaw mechanism, generating neutrino
masses and sizable lepton flavour violating (LFV) entries is assumed to be
operative. In this scheme, we study the complementarity between the `observable
ranges' of various paths leading to the possible discovery of low energy SUSY:
the reach of the Cern Large Hadron Collider (LHC), the quest for neutralino
dark matter signals and indirect searches through LFV processes. Within the
regions of the CMSSMRN parameter space compatible with all
cosmo-phenomenological requirements, those which are expected to be probed at
the LHC will be typically also accessible to upcoming LFV experiments.
Moreover, parameter space portions featuring a heavy SUSY particle spectrum
could be well beyond LHC reach while leaving LFV searches as the only key to
get a glimpse on SUSY.Comment: 31 pages, 12 figures, LateX; v2: one reference and one comment added;
matches with published versio
A Statistical Analysis of Supersymmetric Dark Matter in the MSSM after WMAP
We study supersymmetric dark matter in the general flavor diagonal MSSM by
means of an extensive random scan of its parameter space. We find that, in
contrast with the standard mSUGRA lore, the large majority of viable models
features either a higgsino or a wino-like lightest neutralino, and yields a
relic abundance well below the WMAP bound. Among the models with neutralino
relic density within the WMAP range, higgsino-like neutralinos are still
dominant, though a sizeable fraction of binos is also present. In this latter
case, relic density suppression mechanisms are shown to be essential in order
to obtain the correct neutralino abundance. We then carry out a statistical
analysis and a general discussion of neutralino dark matter direct detection
and of indirect neutralino detection at neutrino telescopes and at antimatter
search experiments. We point out that current data exclude only a marginal
portion of the viable parameter space, and that models whose thermal relic
abundance lies in the WMAP range will be significantly probed only at future
direct detection experiments. Finally, we emphasize the importance of relic
density enhancement mechanisms for indirect detection perspectives, in
particular at future antimatter search experiments.Comment: 39 pages, 25 figure
Precision gamma-ray constraints for sub-GeV dark matter models
The indirect detection of dark matter particles with mass below the GeV scale
has recently received significant attention. Future space-borne gamma-ray
telescopes, including All-Sky-ASTROGAM, AMEGO, and GECCO, will probe the MeV
gamma-ray sky with unprecedented precision, offering an exciting test of
particle dark matter in the MeV-GeV mass range. While it is typically assumed
that dark matter annihilates into only one Standard Model final state, this is
not the case for realistic dark matter models. In this work we analyze existing
indirect detection constraints and the discovery reach of future detectors for
the well-motivated Higgs and vector-portal models using our publicly-available
code Hazma. In particular, we show how to leverage chiral perturbation theory
to compute the dark matter self-annihilation cross sections into final states
containing mesons, the strongly-interacting Standard Model dynamical degrees of
freedom below the GeV scale. We find that future telescopes could probe dark
matter self-annihilation cross sections orders of magnitude smaller than those
presently constrained by cosmic microwave background, gamma-ray and terrestrial
observations.Comment: 20 pages, 4 figure
Direct Detection of Hawking Radiation from Asteroid-Mass Primordial Black Holes
Light, asteroid-mass primordial black holes, with lifetimes in the range between hundreds to several millions times the age of the Universe, are well-motivated candidates for the cosmological dark matter. Using archival COMPTEL data, we improve over current constraints on the allowed parameter space of primordial black holes as dark matter by studying their evaporation to soft gamma rays in nearby astrophysical structures. We point out that a new generation of proposed MeV gamma-ray telescopes will offer the unique opportunity to directly detect Hawking evaporation from observations of nearby dark matter dense regions and to constrain, or discover, the primordial black hole dark matter
A 331 WIMPy Dark Radiation Model
Recent observations suggest that the number of relativistic degrees of
freedom in the early universe might exceed what is predicted in the standard
cosmological model. If even a small, percent-level fraction of dark matter
particles are produced relativistically, they could mimic the effect of an
extra realistic species at matter-radiation equality while obeying BBN, CMB and
Structure Formation bounds. We show that this scenario is quite naturally
realized with a weak-scale dark matter particle and a high-scale ``mother''
particle within a well motivated 3-3-1 gauge model, which is particularly
interesting for being consistent with electroweak precision measurements, with
recent LHC results, and for offering a convincing explanation for the number of
generations in the Standard Model.Comment: 10 pages,7 figures. Matches Published EPJC versio
Increasing the Neutralino Relic Abundance with Slepton Coannihilations: Consequences for Indirect Dark Matter Detection
We point out that if the lightest supersymmetric particle (LSP) is a
Higgsino- or Wino-like neutralino, the net effect of coannihilations with
sleptons is to increase the relic abundance, rather than producing the usual
suppression, which takes place if the LSP is Bino-like. The reason for the
enhancement lies in the effective thermally averaged cross section at
freeze-out: sleptons annihilate (and co-annihilate) less efficiently than the
neutralino(s)-chargino system, therefore slepton coannihilations effectively
act as parasite degrees of freedom at freeze-out. Henceforth, the thermal relic
abundance of LSP's corresponds to the cold Dark Matter abundance for smaller
values of the LSP mass, and larger values of the neutralino pair annihilation
cross section. In turn, at a given thermal neutralino relic abundance, this
implies larger indirect detection rates, as a result of an increase in the
fluxes of antimatter, gamma rays and neutrinos from the Sun orginating from
neutralino pair annihilations.Comment: 16 pages, 6 figures, references added, typos corrected, matches with
the published versio
Astrophysical limitations to the identification of dark matter: indirect neutrino signals vis-a-vis direct detection recoil rates
A convincing identification of dark matter (DM) particles can probably be
achieved only through a combined analysis of different detections strategies,
which provides an effective way of removing degeneracies in the parameter space
of DM models. In practice, however, this program is made complicated by the
fact that different strategies depend on different physical quantities, or on
the same quantities but in a different way, making the treatment of systematic
errors rather tricky. We discuss here the uncertainties on the recoil rate in
direct detection experiments and on the muon rate induced by neutrinos from
dark matter annihilations in the Sun, and we show that, contrarily to the local
DM density or overall cross section scale, irreducible astrophysical
uncertainties affect the two rates in a different fashion, therefore limiting
our ability to reconstruct the parameters of the dark matter particle. By
varying within their respective errors astrophysical parameters such as the
escape velocity and the velocity dispersion of dark matter particles, we show
that the uncertainty on the relative strength of the neutrino and
direct-detection signal is as large as a factor of two for typical values of
the parameters, but can be even larger in some circumstances.Comment: 12 pages, 3 figures. Improved presentation and Fig.3; clarifications,
references and an appendix added; conclusions unchanged. Matches version
published in PR
Semi-Analytic Calculation of the Gravitational Wave Signal From the Electroweak Phase Transition for General Quartic Scalar Effective Potentials
Upcoming gravitational wave (GW) detectors might detect a stochastic
background of GWs potentially arising from many possible sources, including
bubble collisions from a strongly first-order electroweak phase transition. We
investigate whether it is possible to connect, via a semi-analytical
approximation to the tunneling rate of scalar fields with quartic potentials,
the GW signal through detonations with the parameters entering the potential
that drives the electroweak phase transition. To this end, we consider a finite
temperature effective potential similar in form to the Higgs potential in the
Standard Model (SM). In the context of a semi-analytic approximation to the
three dimensional Euclidean action, we derive a general approximate form for
the tunneling temperature and the relevant GW parameters. We explore the GW
signal across the parameter space describing the potential which drives the
phase transition. We comment on the potential detectability of a GW signal with
future experiments, and physical relevance of the associated potential
parameters in the context of theories which have effective potentials similar
in form to that of the SM. In particular we consider singlet, triplet, higher
dimensional operators, and top-flavor extensions to the Higgs sector of the SM.
We find that the addition of a temperature independent cubic term in the
potential, arising from a gauge singlet for instance, can greatly enhance the
GW power. The other parameters have milder, but potentially noticeable,
effects.Comment: accepted by JCAP, revisions: removed turbulence contribution, minor
changes to experimental sensitivity, fixed various minor typos and text
revisions, added references, made it clear we consider only detonations; 17
pages, 4 figures, revtex
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