Experimental Particle Physics Rolling Grant 2006-2011
Lead Research Organisation:
Lancaster University
Department Name: Physics
Abstract
This research is aimed at understanding the properties of the basic building blocks of the Universe (the elementary particles) and the nature of the fundamental forces which govern the interactions of these particles. In so doing, deep insights will be gained about the origin and evolution of the Universe, especially in the first moments after the Big Bang. The Lancaster research programme covers all the main types of accelerator facilities and is based on hadron collider physics with the Tevatron (Fermilab) and LHC (CERN) machines, the observation of long baseline neutrino oscillations in Japan and, in the longer term future, high energy electron-positron collisions at the International Linear Collider (ILC). All of this work will be underpinned by Lancaster's expertise in characterising and understanding the properties of heavily irradiated silicon particle detectors, in operating high performance computing facilities on the Grid and in writing offline event reconstruction software. The hadron collider physics is expected to reveal detailed properties of B hadrons (containing heavy b-quarks) including the mixing of neutral B mesons containing strange quarks, and CP violation which is related to the existence of the matter-antimatter asymmetry in the Universe. Searches for new physics at the LHC will focus on understanding the origin of mass (and the role of the Higgs boson), the existence of new symmetries of nature (e.g. supersymmetry) and extra spatial dimensions. The neutrino oscillations programme is expected to provide important information about the masses of and the amount of mixing amongst the three known species of neutrinos. If the appearance of electron neutrinos can be observed in a muon neutrino beam then it may be possible, in a further phase of the research, to establish the existence of CP violation in the neutrino sector of the Standard Model. This could have wide reaching implications for the understanding of the matter-antimatter asymmetry of the Universe. The electron-positron collider (the ILC) will enable a continuation of some of the research performed at the LHC but with a facility of greater precision and versatility. It could be especially crucial for the elucidation of the properties of the Higgs boson and supersymmetry if they exist as well as being an abundant source of top quraks.
Organisations
Publications
Abazov V
(2012)
Measurement of the top-quark mass in p p ¯ collisions using events with two leptons
in Physical Review D
Abazov V
(2012)
Measurement of the semileptonic charge asymmetry in B 0 meson mixing with the D0 detector
in Physical Review D
Aad G
(2014)
Flavor tagged time-dependent angular analysis of the B s 0 ? J / ? ? decay and extraction of ? G s and the weak phase ? s in ATLAS
in Physical Review D
Abazov V
(2007)
Measurement of the top quark mass in the lepton+jets channel using the ideogram method
in Physical Review D
Abe K
(2013)
Evidence of electron neutrino appearance in a muon neutrino beam
in Physical Review D
Aad G
(2013)
Search for long-lived stopped R -hadrons decaying out of time with p p collisions using the ATLAS detector
in Physical Review D
Abazov V
(2013)
Search for a Higgs boson in diphoton final states with the D0 detector in 9.6 fb - 1 of p p ¯ collisions at s = 1.96 TeV
in Physical Review D
Abazov V
(2006)
Measurement of B d mixing using opposite-side flavor tagging
in Physical Review D
Abazov V
(2012)
Measurement of the C P -violating phase ? s J / ? ? using the flavor-tagged decay B s 0 ? J / ? ? in 8 fb - 1 of p p ¯ collisions
in Physical Review D