NbTiN Nanowire Resonators for Spin-Photon Coupling on Solid Neon

Electrons floating on a solid neon exhibit long charge coherence times, making them attractive for hybrid quantum systems. When combined with high-quality, high-impedance superconducting resonators and a local magnetic field gradient, this platform enables strong charge-photon and spin-charge coupling -- key ingredients for scalable spin qubit architectures. In this work, we fabricated NbTiN superconducting nanowire resonators and measured internal quality factors around $10^5$. We successfully deposited several hundred-nanometer-thick layers of solid neon, followed by gradual electron loading. The presence of neon and electrons was confirmed via resonance frequency shifts without degradation of the resonator's quality factor. These results demonstrate that NbTiN superconducting nanowire resonators are compatible with electrons-on-neon systems and suitable for future qubit experiments. We further performed a theoretical analysis of optimized micro-magnet configurations, showing that spin qubit gate fidelities exceeding 99.99% for single-qubit and 99.9% for two-qubit operations are achievable using natural neon at the charge sweet spot.