Abstract
The 2010-2012 operation period at the LHC has been very successful, includ- ing the discovery of a new particle with a mass of about 125 GeV compatible within uncertainties with the Higgs boson predicted by Standard Model. Precise measurements of the properties of this boson, and the discovery of new physics beyond the Standard Model, are primary goals of future running at the LHC. The physics prospects with a proton-proton centre-of-mass energy of 14 TeV are presented for 300 fb −1 and 3000 fb −1 at the high-luminositiy LHC. The ultimate precision attainable on measurements of the couplings of the 125 GeV particle to elementary fermions and bosons is discussed, as well as perspectives on the searches for partners associated with this new object, predicted by several extensions of the standard theory. Supersymmetry is one of the best motivated and well-studied extensions of the Standard Model. The current searches at the LHC have yielded sensitivity to TeV scale gluinos and 1st and 2nd generation squarks, as well as to 3rd generation squarks and electro-weakinos in the hundreds of GeV mass range. Benchmark studies are presented to show how these limits can be extended for inclusive strong production of squarks and gluinos, direct production of 3rd generation squarks and weak production of electro-weakinos. A considerable fraction of the parameter space for a wide variety of other models has been probed with the 8 TeV data. The prospects of searches for new heavy bosons and dark matter candidates at 14 TeV are explored here. For all these studies, a parameterised simulation of the upgraded ATLAS detector is used, taking into account the expected pileup conditions.
Highlights
The 2010-2012 operation period at the LHC has been very successful, including the discovery of a new particle with a mass of about 125 GeV compatible within uncertainties with the Higgs boson predicted by Standard Model
Analysis of this data has strengthened the validity of the Standard Model, especially in light of the 2012 discovery of the Higgs Boson
Future searches performed in ATLAS at the upgraded LHC aim to further confirm Standard Model measurements, as well as search for deviations from the current theory
Summary
The Standard Model has many inconsistencies and fails to explain many phenomena observed in nature One of these inconsistencies is the divergence of the Higgs mass when calculated beyond leading order. Another inconsistency within the Standard Model is that despite being theoretically possible, experimentally it is observed that Quantum Chromodynamics does not break CP symmetry. Beyond Standard Model Baryogenesis theories provide possible solutions to this question Another Standard Model inconvenience is that the electromagnetic, weak and strong coupling constants do not unify when extrapolated to higher energies. Future searches performed in ATLAS at the upgraded LHC aim to further confirm Standard Model measurements, as well as search for deviations from the current theory. Operation, the analyses were performed based on simulation of < μ >= 60 for 300 f b−1, instead of the currently predicted < μ >= 140
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