上海科技大学知识管理系统

In this paper, we report on a systematic study of the inductance and magnetic field penetration depth (lambda) of polycrystalline NbN superconducting thin films. By employing a four-metal-layer fabrication process specifically designed for all-NbN single-flux-quantum circuits, we constructed a superconducting quantum interference device loop composed of two parallel NbN SNS junctions, NbN microstrips, and NbN ground planes for precise inductance measurement. At 4.2 K, as the linewidth increases from 1 mu m to 30 mu m, the inductance per unit length (L-u) of NbN microstrips significantly decreases, for example, the L-u of 250 nm thick NbN microstrips drops from 0.907 pH/mu m to 0.047 pH/mu m. Compared to Nb, the L-u of polycrystalline NbN microstrips is approximately two to three times that of Nb, offering an advantage for manufacturing smaller superconducting inductors. Furthermore, we conducted simulation analysis using InductEx software to extract the lambda of NbN films of varying thicknesses. The results indicate that as the film thickness increased from 45 nm to 600 nm, lambda initially decreased sharply and then stabilized, with values ranging from 430 nm to 323 nm. Notably, once the film thickness exceeded 200 nm, lambda remained essentially constant, even at a temperature of 10 K, where it showed good stability, albeit with a slight increase (about 50 nm) compared to 4.2 K. This dependence of lambda on thickness is reasonably explained by considering the effects of NbN film thickness on the superconducting critical temperature and residual resistivity. These research findings not only deepen our understanding of the characteristics of superconducting films but also lay a solid foundation for the future design and manufacture of more compact superconducting circuits at the higher temperature of 10 K.