Neutrino oscillation physics at an upgraded CNGS with large next generation liquid Argon TPC detectors
Abstract
The determination of the missing Ue3 element (magnitude and phase) of the PMNS neutrino mixing matrix is possible via the detection of oscillations at a baseline L and energy E given by the atmospheric observations, corresponding to a mass squared difference E/L m2 2.5× 10-3 eV2. While the current optimization of the CNGS beam provides limited sensitivity to this reaction, we discuss in this document the physics potential of an intensity upgraded and energy re-optimized CNGS neutrino beam coupled to an off-axis detector. We show that improvements in sensitivity to θ13 compared to that of T2K and NoVA are possible with a next generation large liquid Argon TPC detector located at an off-axis position (position rather distant from LNGS, possibly at shallow depth). We also address the possibility to discover CP-violation and disentangle the mass hierarchy via matter effects. The considered intensity enhancement of the CERN SPS has strong synergies with the upgrade/replacement of the elements of its injector chain (Linac, PSB, PS) and the refurbishing of its own elements, envisioned for an optimal and/or upgraded LHC luminosity programme.
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