Measuring and Modeling Radiation Loss in Superconducting Microwave Re-entrant Cavities

Undergraduate Honors Thesis

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Citeable URL: https://scholar.colorado.edu/concern/undergraduate_honors_theses/2z10wq768

Abstract

This thesis describes the potential use of re-entrant microwave resonant three-dimensional cavities as low-loss electrical component in strongly coupled electromechanical systems. In particular, I have investigated radiative processes as a loss mechanism of a re-entrant cavity in a geometry similar to those used in electromechanical experiments undertaken by the Lehnert lab. First, I present the veri cation of a lumped-element model describing the cavity resonance, a key electrical characteristic of a microwave re-entrant cavity, and its dependence on dimensions critical to strong electromechanical coupling. Next, I focus on modeling and measuring the total power radiating from a re-entrant cavity. To this end, I evaluated the e ectiveness of surrounding the re-entrant cavity with a waveguide "choke" ange as a method of reducing total radiated power. The experimental results show the energy dissipation rate from radiation can be reduced by at least 5x10^4 after incorporating a radiation choke ange. This experiment aimed to inform whether a cavitywith a quality factor that is limited by radiation losses is satisfactory to achieve single-photon coupling g0 greater than , the electromagnetic energy dissipation rate, in an electromechanical device. The pursuit of strong single-photon electromechanical coupling is the motivation of my investigations of radiation loss in superconducting microwave re-entrant cavities.

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