Conveners
Working Group 1+2: Detector Technology-1
- Zhimin Wang (Institute of high energy physics, Beijing)
Working Group 1+2: Detector Technology-2
- adi ashkenazi
-
Alan Bross (Fermilab)29/08/2019, 14:00Oral Presentation
-
Jianming Bian (University of California Irvine (US))29/08/2019, 14:22Oral Presentation
-
Dr Kostas Mavrokoridis (University of Liverpool)29/08/2019, 14:44Oral Presentation
ARIADNE, a state-of-the-art 1-ton two-phase Liquid Argon Time Projection Chamber (LAr TPC), features a game-changing photographic readout utilising photon sensitive cameras to image the secondary scintillation light produced in THGEM holes. ARIADNE underwent testing at the T9 beam line, CERN East Area in Spring 2018. ARIADNE is the first two-phase LAr TPC with photographic capabilities to be...
Go to contribution page -
Jilei Xu (Institute of High Energy Physics, Chinese Academy of Sciences)29/08/2019, 15:06Oral Presentation
The JUNO detector was designed to achieve 3% energy resolution which required 18k high quantum efficiency 20-inch PMTs (LPMTs) closely packed around liquid scintillator (LS) target ball. Beside this, 25k 3-inch PMTs (SPMTs) were also designed to install between the gaps of LPMTs to make a double calorimetry system to improve and extend JUNO physics, such as improving energy resolution, muon...
Go to contribution page -
Marco Zito (Université Paris-Saclay (FR)), John Nugent (University of Glasgow)29/08/2019, 16:00
In view of the J-PARC program of upgrades of the beam intensity, the T2K collaboration is preparing towards an increase of the exposure aimed at establishing leptonic CP violation at 3 $\sigma$ level for a significant fraction of the possible $\delta_{CP}$ values. To reach this goal, an upgrade of the T2K near detector ND280 has been launched, with the aim of reducing the overall statistical...
Go to contribution page -
Kenji Yasutome (Kyoto University)29/08/2019, 16:22Oral Presentation
WAGASCI-BabyMIND is a set of new neutrino detectors to measure the neutrino cross-section with the T2K neutrino beam. It is composed of neutrino detectors made of water and scintillator surrounded by muon range detectors made of iron and scintillator. The downstream muon range detector is magnetized to discriminate the charge of the muons. It is located in the same building as ND280 but at the...
Go to contribution page -
Tsutomu Fukuda (Toho university)29/08/2019, 16:44Oral Presentation
Nuclear emulsion is a three dimensional tracking detector with
Go to contribution page
sub-micron resolution. Thanks to its high spatial resolution, emulsion
can detect short-length low energy tracks and measure track angle
precisely in neutrino/hadron interactions. Moreover, the emulsion has 4
pi solid angle acceptance (it's also useful to measure low energy
tracks) and can use target materials flexibly,... -
Francesco Terranova (Universita & INFN, Milano-Bicocca (IT))29/08/2019, 17:06
The knowledge of initial flux, energy and flavor of current neutrino beams is currently the main limitation for a precise measurement of neutrino cross sections. The ENUBET ERC project (2016-2021) is studying a facility based on a narrow band neutrino beam capable of constraining the neutrino fluxes normalization through the monitoring of the associated charged leptons in an instrumented decay...
Go to contribution page -
Mr Hitoshi Oshima (Toho University)29/08/2019, 17:28Oral Presentation
Understanding of neutrino-nucleus interactions for energies around 1 GeV is of great importance to us because one of the major systematic uncertainties in current neutrino oscillation experiments comes from nuclear effects in those interactions.
Go to contribution page
The NINJA collaboration aims to study neutrino-nucleus interactions in the energy range of hundreds of MeV to a few GeV by using emulsion-based... -
TBDOral Presentation