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   https://doi.org/10.1109/TED.2019.2924312  

   Milosevic, Erik; Kerdsongpanya, Sit; McGahay, Mary E.; Wang, Baiwei; Gall, Daniel (August 2019, IEEE Transactions on Electron Devices)
2. Thermodynamic re-modelling of the Cu–Nb–Sn system: Integrating the nausite phase

   https://doi.org/10.1016/j.calphad.2022.102409  

   Lachmann, Jonas; Kriegel, Mario J.; Leineweber, Andreas; Shang, Shun-Li; Liu, Zi-Kui (June 2022, Calphad)
3. Measurements of the amplitude-dependent microwave surface resistance of an Au/Nb bilayer

   https://doi.org/10.1088/1361-6668/acf88d  

   Oseroff, Thomas; Sun, Zeming; Liepe, Matthias U (September 2023, Superconductor Science and Technology)

   Abstract Surface properties are critical to the capabilities of superconducting microwave devices. The native oxide of niobium-based devices is thought to consist of a thin normal conducting layer. To improve understanding on the importance of this layer, an attempt was made to replace it with a more easily controlled gold film. A niobium sample host microwave cavity was used to measure the surface resistance in continuous wave operation at $4.0\text{GHz}$and $5.2\text{GHz}$. Sample conditions studied include temperatures ranging from $1.6\text{K}$to $4.2\text{K}$with RF magnetic fields on the sample surface ranging from $\sim 1\text{mT}$to the maximum field before the superconducting properties were lost (quench field). The nominal film thickness of the gold layer was increased from $0.1\text{nm}$to $2.0\text{nm}$in five steps to study the impact of the normal layer thickness on surface resistance on a single niobium substrate. The $0.1\text{nm}$film was found to reduce the surface resistance of the sample and to enhance the quench field. With the exception of the final step from a $1.5\text{nm}$gold film to $2.0\text{nm}$, the magnitude of the surface resistance increased substantially with gold film thickness. The nature of the surface resistance field-dependence appeared to be roughly independent from the gold layer thickness. This initial study provides new perspectives and suggests avenues for optimizing and designing surfaces for resonant cavities in particle accelerators and quantum information applications. 

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4. Fracture resistance of Cu/Nb metallic nanolayered composite

   https://doi.org/10.1557/jmr.2019.115  

   Huang, Sixie; Zhou, Caizhi (May 2019, Journal of Materials Research)

   In this work, molecular dynamics simulations to explore the crack propagation and fracture behavior of Cu/Nb metallic nanolayered composites (MNCs) were performed. The results of this study are consistent with the previous experimental results, which illustrated that cracks in Cu and Nb layers may exhibit different propagation paths and distances under the isostrain loading condition. The analysis reveals that the interface can increase the fracture resistance of the Nb layer in Cu/Nb MNCs by providing the dislocation sources to generate the plastic strain at the front of the crack. Increasing the layer thickness can enhance the fracture resistance of both Cu and Nb layers, as the critical stress for activating the dislocation motion decreases with the increment of the layer thickness. In addition, grain boundaries (GBs) in polycrystalline Cu/Nb samples would decrease the fracture resistance of Nb layer by promoting the crack propagate along the GBs, i.e., intergranular fracture, while the effect of interface and layer thickness on the fracture resistance of MNCs will not be altered by introducing the GBs in MNCs. 

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5. Thermal stability of 3D interface Cu/Nb nanolaminates

   https://doi.org/10.1016/j.scriptamat.2024.116319  

   Cheng, Justin Y; Li, Zezhou; Poerschke, David L; Baldwin, J Kevin; Bresnahan, Brady L; Mara, Nathan A (January 2025, Scripta Materialia)