Physics at future hadron colliders

  title={Physics at future hadron colliders},
  author={U. Baur and R. Brock and J. P. M. Albrow and D. Denisov and T. Han and A. Kotwal and F. Olness and J. Qian and S. Belyaev and E. al.},
We discuss the physics opportunities and detector challenges at future hadron colliders. As guidelines for energies and luminosities we use the proposed luminosity and/or energy upgrade of the LHC (SLHC), and the Fermilab design of a Very Large Hadron Collider (VLHC). We illustrate the physics capabilities of future hadron colliders for a variety of new physics scenarios (supersymmetry, strong electroweak symmetry breaking, new gauge bosons, compositeness and extra dimensions). We also… Expand
Examining the Higgs boson potential at lepton and hadron colliders: A comparative analysis
We investigate inclusive Standard Model Higgs boson pair production at lepton and hadron colliders for Higgs boson masses in the range 120 GeV 140 GeV we examine ZHH and HH nu bar-nu production at aExpand
Searches for supersymmetry at high-energy colliders: the past, the present and the future
The present status of the experimental searches for supersymmetry at LEP and Tevatron is reviewed. Prospects at future machines, i.e. the Large Hadron Collider and lepton colliders, are alsoExpand
Prospects for Higgs physics at energies up to 100 TeV.
The prospects for Higgs boson physics at future proton-proton colliders with centre of mass (c.m.) energies up to 100 TeV are summarized and the sensitivity of a 100 Tev proton machine to probe the new Higgs states is discussed and compared to that of the LHC with a c.m. energy of 14 TeV. Expand
Future collider signatures of the possible 750 GeV state
A bstractIf the recent indications of a possible state Φ with mass ~ 750 GeV decaying into two photons reported by ATLAS and CMS in LHC collisions at 13 TeV were to become confirmed, the prospectsExpand
Determining the Higgs boson self-coupling at hadron colliders
Inclusive Standard Model Higgs boson pair production at hadron colliders has the capability to determine the Higgs boson self-coupling, .W e present a detailed analysis of the gg ! HH ! (W + W )(W +Expand
Searching for new physics at CDF
We present recent results on searches for physics beyond the Standard Model obtained from the analysis of 1 fb{sup -1} of data collected at the Tevatron Collider by the CDF Collaboration. We reportExpand
Studying the Higgs Sector at the CLIC Multi-TeV $e^+e^-$ Collider
In this paper, we review the role of a multi-TeV $e^+e^-$ linear collider to complete the mapping of the Higgs boson profile and studying heavier bosons in extended scenarios with more than one HiggsExpand
Measuring the top-quark Yukawa coupling at hadron colliders via tt̄h,h→W +W -
We study the signal and backgrounds for the process $t\overline{t}h,\stackrel{\ensuremath{\rightarrow}}{h}{W}^{+}{W}^{\ensuremath{-}}$ at the CERN Large Hadron Collider (LHC) and a 100 TeV Very LargeExpand
Dark Matter through the Higgs portal
We review scenarios in which the particles that account for the Dark Matter (DM) in the Universe interact only through their couplings with the Higgs sector of the theory, the so-called Higgs-portalExpand
Silicon detectors for the next generation of high energy physics experiments: expected degradation
There exists an enormous interest for the study of very high energy domain in particle physics, both theoretically and experimentally, in the aim to construct a general theory of the fundamentalExpand


The MARS code system user's guide version 13(95)
This paper is a user’s guide to the current version of the MARS Monte Carlo code. MARS performs fast inclusive simulations of three-dimensional hadronic and electromagnetic cascades, muon and lowExpand
The Compact Muons Solenoid
  • Technical Proposal”,
  • 1994
  • Rev. D63, 015011
  • 2001
  • Phys. B261, 379 (1985); V. Barger et al., Phys. Rev. D42, 3052 (1990); J. Bagger et al., Phys. Rev. D49, 1246 (1994); Phys. Rev. D52, 3878
  • 1995
  • Phys. Commun. 135, 238
  • 2001
JHEP 0101
  • 010
  • 2001
  • Rev. Lett. 84, 2080 (2000); Phys. Lett. B493, 135 (2000); and Phys. Rev. D63, 075004
  • 2001
  • Lett. B520, 108
  • 2001
  • Rev. Lett. 87, 161602
  • 2001
The DØ Collaboration
We present a study of eeγ and μμγ events using 1109 (1009) pb−1 of data in the electron (muon) channel, respectively. These data were collected with the DØ detector at the Fermilab Tevatron pp̄Expand