📝 SummarXiv

Abstract

The performance and scalability of cryogenic microwave systems, particularly for quantum processors, are fundamentally limited by the thermal stability and loss of their constituent dielectric materials. While mixed titanate ceramics like MgTiO3-CaTiO3 (MCT) and (Zr,Sn)TiO4 (ZST) are primary candidates, their comparative performance as radiative antennas in the deep-cryogenic regime has remained uncharacterized. Here we present a side-by-side comparison of MCT and ZST operated as dielectric resonator antennas from 296 K down to 7-10 K under identical fixtures and protocols. While the MCT resonator exhibits large, nonlinear frequency drift (230 MHz by 10 K), pronounced thermal hysteresis, and a collapse of the loaded quality factor at low temperature-behavior consistent with incipient/relaxor-like losses, the ZST resonator demonstrates exceptional stability. Its resonant frequency shifts by only 30 MHz, its loaded Q-factor is enhanced by 20-25%, and it shows negligible thermal hysteresis. Leveraging these properties, we operate the ZST disk as a radiative antenna at 10 K with only 1 mW input, establishing a through-window wireless link that detects room-temperature dielectric targets over multiple wavelengths via near-field frequency shifts and far-field magnitude modulations. This presents a viable path toward non-invasive cryogenic diagnostics and wireless interconnects that circumvent the thermal load of physical cabling. Our findings establish ZST as a foundational material for high-coherence quantum interfaces and provide a practical template for designing wireless cryogenic systems.