Search For Dark Photons From Neutral Meson Decays In Mathmip Mimo Momip Mi Math And Mathmid Mimo Momi Mathvariant PDF Download

Dark matter makes up 85% of the matter in the universe and 27% of its energy density, but we don’t know what comprises dark matter. There are several compelling candidates for dark matter that have wavelike properties, including axions and dark photons. Wavelike dark matter can be detected using ultra-sensitive microwave cavities. The ADMX experiment usesa cylindrical cavity operating at the fundamental mode to search for axions in the few [microelectronvolt] mass range. However, the ADMX search technique becomes increasingly challenging with increasing axion mass. This is because higher masses require smaller-diameter cavities, and a smaller cavity volume reduces the signal strength. Thus, there is interest in developing more sophisticated resonators to overcome this problem. The ADMX-Orpheus experiment uses a dielectric-loaded Fabry-Perot cavity to search for axions and dark photons with masses approaching 100 [microelectronvolts]. Orpheus maintains a large volume by operating at a higher-order mode, and the dielectrics shape the electric field so that the mode couples more strongly to the axion and dark photon. This thesis describes the development and commissioning of ADMX-Orpheus to search for dark photons with masses between 65.5 [microelectronvolts] and 69.3 [microelectronvolts]. This thesis includes motivation for why dielectric cavities are suitable for detecting axions and dark photons around 100 [microelectronvolts]; the design and characterization of such a cavity, including the resonant frequency, quality factor, and detection volume of the mode of interest; the mechanical design, electronics, and data acquisition system for the Orpheus experiment; the inaugural search for dark photons 65.5 [microelectronvolts] and 69.3 [microelectronvolts]; and the resulting excluded parameter space; plans for upgrading Orpheus to search for axions in a similar mass range.