Aune, S.Bortfeldt, J.Brunbauer, F.David, C.Desforge, D.Fanourakis, G.Gallinaro, M.Garcia, F.Giomataris, IGustavsson, T.Iguaz, F. J.Kebbiri, M.Kordas, K.Lampoudis, C.Legou, P.Lisowska, M.Liu, J.Lupberger, M.Maillard, O.Maniatis, IManthos, IMueller, H.Oliveri, E.Papaevangelou, T.Paraschou, K.Pomorskik, M.Qi, B.Resnati, F.Ropelewski, L.Sampsonidis, D.Scharenberg, L.Schneider, T.Sohl, L.van Stenis, M.Tsiamis, A.Tsipolitis, Y.Tzamarias, S. E.Utrobicic, A.Wang, X.White, S.Zhang, Z.Zhou, Y.2024-06-062024-06-062021-01-290168-9002https://doi.org/10.1016/j.nima.2021.165076https://hdl.handle.net/11452/41792The multi-pad PICOSEC-Micromegas is an improved detector prototype with a segmented anode, consisting of 19 hexagonal pads. Detailed studies are performed with data collected in a muon beam over four representative pads. We demonstrate that such a device, scalable to a larger area, provides excellent time resolution and detection efficiency. As expected from earlier single-cell device studies, we measure a time resolution of approximately 25 picoseconds for charged particles hitting near the anode pad centres, and up to 30 picoseconds at the pad edges. Here, we study in detail the effect of drift gap thickness non-uniformity on the timing performance and evaluate impact position based corrections to obtain a uniform timing response over the full detector coverage.eninfo:eu-repo/semantics/openAccessGaseous detectorsMicromegasMulti-padTime resolutionScience & technologyTechnologyPhysical sciencesInstruments & instrumentationNuclear science & technologyPhysics, nuclearPhysics, particles & fieldsInstruments & instrumentationNuclear science & technologyPhysicsArticle00062981610000499310.1016/j.nima.2021.165076