98 research outputs found
Long-lived Colored Scalars at the LHC
We study the collider signatures of a long-lived massive colored scalar
transforming trivially under the weak interaction and decaying within the inner
sections of a detector such as ATLAS or CMS. In our study, we assume that the
colored scalar couples at tree-level to a top quark and a stable fermion,
possibly arising from a dark sector or from supersymmetric extensions of the
Standard Model. After implementing the latest experimental searches for
long-lived colored scalars, we observe a region of parameter space consistent
with a colored electroweak-singlet scalar with mass between GeV
and a lifetime between together, with a nearly degenerate
dark fermion that may be probed at the TeV LHC. We show that a
search strategy using a combination of cuts on missing transverse energy and
impact parameters can exclude regions of parameter space not accessed by prompt
searches. We show that a region of parameter space within our simplified model
may naturally arise from the light-stop window regime of supersymmetric
extensions of the Standard Model, where a light mostly right-handed stop has a
mass slightly larger than the lightest neutralino and decays through a
four-body process
Slim SUSY
The new SM-like Higgs boson discovered recently at the LHC, with mass 125 GeV, as well as the direct LHC bounds on the mass of superpartners,
which are entering into the TeV range, suggest that the minimal surviving
supersymmetric extension of the SM (MSSM), should be characterized by a heavy
SUSY-breaking scale. Several variants of the MSSM have been proposed to account
for this result, which vary according to the accepted degree of fine-tuning. We
propose an alternative scenario here, Slim SUSY, which contains sfermions with
multi-TeV masses and gauginos/higgsinos near the EW scale, but it includes the
heavy MSSM Higgs bosons (, , ) near the EW scale too. We
discuss first the formulation and constraints of the Slim SUSY scenario, and
then identify distinctive heavy Higgs signals that could be searched at the
LHC, within scenarios with the minimal number of superpartners with masses near
the EW scale.Comment: 16 pages, 6 figures. Section 2 has been restructured, with a new
subsection and some comments added. This version matches the manuscript
accepted in Physics Letters
Top-antitop resonance searches beyond 1 TeV
We perform a general parton level analysis for the search of heavy resonant
states in the production of top-antitop pairs at the LHC with an integrated
luminosity of 30 fb^-1. We assume the existence of resonances that only couple
to quarks and propose kinematic cuts in order to increase the amount of events
produced through quark-annihilation. We study the interplay between different
variables and their impact on the purity of the selected sample. We make focus
on the longitudinal () and transverse () momentum of the
top-antitop pair, and the scattering angle () in the center of mass
reference frame. We observe that is replaced by as a suitable
discriminating variable of quark-annihilation processes for invariant masses
above 1 TeV. Finally, we illustrate the analysis with a gluon resonance of 1.5
TeV and show the improvement in the sensitivity of the signal when cuts on
are imposed.Comment: 19 pages and 6 figure
Decays of in supersymmetric scenarios with heavy sfermions
The recent discovery of a new boson at the LHC, which resembles a SM-like
Higgs boson with GeV, is starting to provide strong guidelines into
SUSY model building. For instance, the identification of such a state with the
lightest CP-even Higgs boson of the MSSM (), requires large values of
and/or heavy sfermions. One outcome of this result is the
possibility to solve the SUSY flavor and CP problems by decoupling, which
points towards some realization of Split-inspired SUSY scenarios, in which
scalars are much heavier than gauginos and higgsinos. However, we argue here
that the remaining Higgs bosons of the MSSM (, , ) do not
have to be as heavy as the sfermions, and having them with masses near the EW
scale does not pose any conflict with current MSSM constraints. We discuss then
some SUSY scenarios with heavy sfermions, from a bottom-up approach, which
contain the full Higgs sector, as well as a possible dark matter candidate,
with masses near the EW scale, and identify distinctive signals from these
scenarios that could be searched at the LHC.Comment: 25 pages, 12 figures. Title modified, one figure and some comments
added, overall conclusions remained as previous versions. This last version
matches the manuscript accepted in EPJ
Detecting New Physics in Rare Top Decays at the LHC
In the companion paper it was shown that there are six observables in that can be used to reveal
the presence of new physics (NP) in . In the present paper we
examine the prospects for detecting and identifying such NP at the LHC, in both
the short term and long term. To this end, we develop an algorithm for
extracting the NP parameters from measurements of the observables. In the short
term, depending on what measurements have been made, there are several
different ways of detecting the presence of NP. It may even be possible to
approximately determine the values of certain NP parameters. In the long term,
it is expected that all six observables will be measured. The values of the NP
parameters can then be determined reasonably precisely from a fit to these
measurements, which will provide good information about the type of NP present
in .Comment: Published versio
Long-lived colored scalars at the LHC
We study the collider signatures of a long-lived massive colored scalar transforming trivially under the weak interaction and decaying within the inner sections of a detector such as ATLAS or CMS. In our study, we assume that the colored scalar couples at tree-level to a top quark and a stable fermion, possibly arising from a dark sector or from supersymmetric extensions of the Standard Model. After implementing the latest experimental searches for long-lived colored scalars, we observe a region of parameter space consistent with a colored electroweak-singlet scalar with mass between ∼200–350 GeV and a lifetime between 0.1–1 mm/c together, with a nearly degenerate dark fermion that may be probed at the √s = 13 TeV LHC. We show that a search strategy using a combination of cuts on missing transverse energy and impact parameters can exclude regions of parameter space not accessed by prompt searches. We show that a region of parameter space within our simplified model may naturally arise from the light-stop window regime of supersymmetric extensions of the Standard Model, where a light mostly right-handed stop has a mass slightly larger than the lightest neutralino and decays through a four-body process.Instituto de Física La Plat
Vertex Displacements for Acausal Particles: Testing the Lee-Wick Standard Model at the LHC
We propose to search for wrong displaced vertices, where decay products of
the secondary vertex move towards the primary vertex instead of away from it,
as a signature for microscopic violation of causality. We analyze in detail the
leptonic sector of the recently proposed Lee-Wick Standard Model, which
provides a well motivated framework to study acausal effects. We find that,
assuming Minimal Flavor Violation, the Lee-Wick partners of the electron,
{\tilde l}^e and \tilde e, can produce measurable wrong vertices at the LHC,
the most promising channel being q \bar{q} --> \bar{\tilde l}^e {\tilde l}^e
--> e^+ e^- jjjj. A Monte-Carlo simulation using MadGraph/MadEvent suggests
that for M_l < 450 GeV the measurement of these acausal vertex displacements
should be accessible in the LHC era.Comment: 29 pages, 7 figures, minor changes, published versio
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