It is an exceptional time for discoveries in particle physics and particle astrophysics and the research we wish to conduct in this STFC consolidated grant programme at Sheffield is at the heart of this action. Foremost recently has been the discovery by ATLAS of a Higgs boson particle. Members of the group led and helped to develop the key 4-lepton analysis upon which the discovery was based. We will now use our expertise to measure carefully the properties of the new particle to establish whether it is the Higgs boson predicted by theory, or something else. We will also search for squark and gluino particles predicted by supersymmetry theory, which will be the main target of the next, higher energy, run of the LHC. Preparing for the future, we will expand our role in the ATLAS upgrade programme to build key components of a new ATLAS tracker. Our involvement in the T2K experiment in Japan also greatly benefited from confirmation of a non-zero third neutrino mixing angle, a result fundamental to our understanding of the neutrino. The group's respected work in neutrino analyses for T2K, particularly of so-called charge current and neutral current events, will continue along with international responsibilities for data management and for the critical light injection calibration system. However, bolstered by the exciting new results we will now also accelerate participation in next generation long baseline neutrino experiment for CP violation aimed to unravel the mystery of antimatter in the Universe, notably using LBNE/F in the US and Hyper-K in Japan. For these our particular focus will be on detector construction. For the precursor LAr1-ND experiment at Fermilab we plan to construct the central Anode Plane Array for the detector, while working also on our pioneering liquid argon R&D. We will also establish novel detector prototypes at the new CERN-based neutrino platform and for LBNE/F itself. Closely related here will be work on the MICE experiment towards a potential future neutrino factory, plus related R&D on high power particle beam targets for future neutrino beams and experiments. For particle astrophysics we plan to expand work on gravitation waves, through specialist noise analysis for Advanced Ligo, and develop new effort on dark matter, thought to comprise 90% of the Universe. There is strong motivation here because the US LUX experiment recently produced a step-change in sensitivity to dark matter particles. We will complete leading analysis for the EDELWEISS experiment and then lead key simulations for the upcoming LZ experiment in the US. Following our pioneering work on detectors with sensitivity to galactic signatures, the group will also lead analysis and construction tasks for the DRIFT direction sensitive experiment at Boulby and the new DM-ICE250 NaI experiment, which US collaborators recently agreed will be hosted at Boubly. DM-ICE will seek a new annual modulation signal for dark matter. These experiments are all searching WIMP particles, but we will also expand study of axions as a potential alternative. Meanwhile, our generic detector R&D and knowledge exchange programme is vital to underpinning the group's expertise and skills-base. It benefits from our historic links to the Boulby deep underground science laboratory but critically now involves multiple industrial and non-STFC projects. Noteworthy aims now will be to complete our DECC-funded programme on muon tomography for climate change, develop new instrumentation for radon assay, spin-out work on novel motor control electronics via a new patent and continue development of novel welding technology. It is interesting that our long-standing efforts to develop liquid argon technology for neutrino physics are also relevant to medical imaging requirements. We plan to complete a new prototype instrument, building on a recent MRC award. This all reflects the group's commitment to contributing to societal and impact agendas.