The studies performed in this project helped clarify that precision timing can make a significant impact on the event reconstruction at future colliders.
Because of the limited timing resolution and relatively modest amount of pileup at current LHC experiments, algorithms exploiting precision timing for pileup mitigation in event reconstruction were still at an early stage at the beginning of the project. Software tools have been developed and several studies on physics objects and benchmarks channels performed. These studies indicate that precision timing can have a major impact on the physics program of the HL-LHC, whose priorities will be the precision study of the Higgs boson properties and direct searches for new phenomena at the TeV scale. By exploiting precision timing, Higgs measurements will benefit from the improved determination of the hard interaction vertex and from the improved acceptance of isolated objects, which translate in a sizable gain in equivalent integrated luminosity. Searches for new phenomena will benefit both from the increase in acceptance and from ameliorations in the reconstruction of spatially extended or global event variables, like jets and missing transverse energy, which will considerably extend the sensitivity of these searches.
On the instrumental side, we have proven the viability of microchannel plates for the measurement of minimum ionising tracks and for electromagnetic showers, with efficiencies and time resolutions suitable for the realisation of a precision timing layer. The achievement of a resolution of a few 10 ps, which is one order of magnitude better than the one at the current LHC experiments, represents, therefore, a major progress in the research field; the possibility to use MCPs as secondary emission device, as investigated in this project, presents advantages in terms of easier and cost effective detector assembly. Also, although this project focused on applications in high energy physics, a wider impact is expected with interesting applications in other fields like in medical imaging for the realisation of TOF-PET (Time Of Flight Positron Emission Tomography) systems.