Study of Light Backgrounds from Relativistic Electrons in Air Light-Guides

The MOLLER experiment proposed at the Thomas Jefferson National Accelerator Facility plans a precise low energy determination of the weak mixing angle via the measurement of the parity-violating asymmetry in the scattering of high energy longitudinally polarized electrons off target electrons (M{\o}ller scattering). A relative measure of the scattering rate is planned to be obtained by intercepting the M{\o}ller scattered electrons with a circular array of thin fused silica tiles attached to air light guides, facilitating the transport of Cherenkov photons generated in the tiles to photomultiplier tubes (PMTs). The scattered flux must inevitably also pass through neighboring light guides, generating additional Cherenkov as well as scintillation light; background that will be detected by the PMT as well. In order to estimate the rate of these backgrounds, a dedicated tube detector was designed and deployed in an electron beam test at the MAMI facility at Johannes Gutenberg University, Mainz. In the test, not only air but also other gases were studied as a background medium. In this paper, the simple design of a general purpose detector to separately measure the scintillation and Cherenkov responses in gas mixtures from traversing relativistic electrons will be described, as well as the results of our studies including beam test data analysis and Geant4 simulations, and our conclusions about the implications for the design of the MOLLER detector apparatus.