The MUSE Target Chamber Post Veto
/ Authors
R. Ratvasky, T. Rostomyan, M. Ali, H. Atac, F. Barchetti, J. Bernauer, W. Briscoe, A. Ndukwe, E. W. Cline, S. Das
and 39 more authors
K. Deiters, E. Downie, Z. Duan, A. Flannery, M. Foster, A. Friebolin, M. Gantert, R. Gilman, A. Golossanov, J. Guo, J. Hirschman, A. Hofer, N. Ifat, Y. Ilieva, D. Jayakodige, T. Krahulik, M. Kohl, I. Lavrukhin, W. Lin, W. Lorenzon, P. Mohanmurthy, M. Nicol, M. Paolone, T. Patel, A. Prosnyakov, R. Ransome, R. Raymond, H. Reid, P. Reimer, R. Richards, G. Ron, O. Ruimi, K. Salamone, S. Shrestha, N. Sparveris, S. Strauch, N. Wuerfel, D. Yaari, C. Zimmerli
/ Abstract
The Muon Scattering Experiment (MUSE) was developed to address the proton radius puzzle through simultaneous electron-proton and muon-proton scattering using the Paul Scherrer Institute's PiM1 secondary beamline. MUSE uses a large-solid-angle, non-magnetic spectrometer to detect beam particles scattering from a liquid hydrogen cell contained within a vacuum chamber. Due to the large scattering windows, the structural integrity of the chamber is supported by posts located at small scattering angles. While out of the acceptance, particles in the tails of the beam distribution can strike these posts, causing a significant trigger background. We describe the design and performance of the Target Chamber Post Veto (TCPV) detector installed inside the vacuum chamber to remove these background events at the trigger level.