The Standard Model and Beyond
Lead Research Organisation:
University of Edinburgh
Department Name: Sch of Physics and Astronomy
Abstract
Currently, our understanding of Nature at the most fundamental level is at the crossroads. This year, the LHC at CERN will collide protons at higher energies than ever before, sufficient to explore physics in depth at the TeV scale. Nobody yet knows what these data will reveal. However, there are very good reasons to believe that something fundamentally new will be discovered, which might transform our understanding of basic physics, making the next few years the most exciting time for a generation or more. The discoveries could be new types of particle, such as the Higgs boson, new kinds of symmetries such as supersymmetry, or indeed something even more dramatic such as extra dimensions. Our rolling programme of research in Particle Physics Theory at the University of Edinburgh is designed to be at the forefront of these new discoveries: indeed Peter Higgs himself is Emeritus Professor here. Specifically, we provide theoretical calculations, using pen and paper, and the most powerful supercomputers, of both the huge number of background processes to be seen at LHC due to known physics, and the tiny signals expected in various models of new physics, in order to discriminate between signal and background, and thus maximise the discovery potential of the LHC. In parallel, we will attempt to understand the more complete picture of all the forces of Nature that should begin to emerge, in our ultimate quest for a Theory of Everything.
Organisations
Publications
Ball P
(2008)
Distribution amplitudes of the ? b baryon in QCD
in Physics Letters B
Oliveira O
(2009)
Does the lattice zero-momentum gluon propagator for pure-gauge SU(3) Yang-Mills theory vanish in the infinite-volume limit?
in Physical Review D
Arthur R
(2013)
Domain wall QCD with near-physical pions
in Physical Review D
Fischer A
(2009)
Duality covariant quantum field theory on noncommutative Minkowski space
in Journal of High Energy Physics
Guo FK
(2015)
Electric Dipole Moment of the Neutron from 2+1 Flavor Lattice QCD.
in Physical review letters
Shanahan P
(2014)
Electric form factors of the octet baryons from lattice QCD and chiral extrapolation
in Physical Review D
Boinepalli S
(2009)
Electromagnetic structure of decuplet baryons towards the chiral regime
in Physical Review D
Braun VM
(2009)
Electroproduction of the N*(1535) resonance at large momentum transfer.
in Physical review letters
Boyle PA
(2013)
Emerging understanding of the ?I=1/2 rule from lattice QCD.
in Physical review letters
McComb WD
(2015)
Energy transfer and dissipation in forced isotropic turbulence.
in Physical review. E, Statistical, nonlinear, and soft matter physics
Description | Lots of interesting Particle Physics |
Exploitation Route | Lots of ways |
Sectors | Digital/Communication/Information Technologies (including Software),Education |