Addressing experimental issues in axion haloscope searches

The cavity haloscope provides a highly sensitive method to search for dark matter axions in the microwave regime. Experimental attempts to enhance the sensitivity have focused on improving major aspects, such as producing strong magnetic fields, increasing cavity quality factors, and achieving possible lowest possible noise temperatures. Some issues, however, which have arisen in realistic designs or empirically observed while conducting experiments may not have been properly addressed. They are associated with non-uniform magnetic fields over the detection volume, noise propagation under attenuation and temperature gradients, and thermal disequilibrium in the cavity system. In this report, we devise analytical approaches to address these issues to investigate the non-trivial effects and provide potential solutions for better treatment and performance.