Tiziana Spina scite author profile

We report on atomic-scale analyses using high-resolution scanning transmission electron microscopy (HR-STEM), atom-probe tomography (APT), and first-principles calculations to study grain-boundary (GB) segregation behavior of Nb 3 Sn coatings on Nb, prepared by a vapor-diffusion process for superconducting radiofrequency (SRF) cavity applications. The results reveal Sn segregation at GBs of some Nb 3 Sn coatings, with a Gibbsian interfacial excess of ~10-20 Sn atoms/nm 2 . The interfacial width of Sn segregation at a GB is ~3 nm, with a maximum concentration of ~35 at.%. HR-STEM imaging of a selected [12 ̅ 0] tilt GB displays a periodic array of the structural unit at the core of the GB, and firstprinciple calculations for the GB implies that excess Sn in bulk Nb 3 Sn may segregate preferentially at GBs to reduce total internal energy. The amount of Sn segregation is correlated with two factors: (i) Sn supply; and (ii) the temperatures of the Nb substrate and Sn source, which may affect the overall kinetics including GB diffusion of Sn and Nb, and the interfacial reaction at Nb 3 Sn/Nb interfaces. An investigation of the correlation between the chemistry of GBs and Nb 3 Sn SRF cavity performance reveals no significant Sn segregation at GBs of high-performance Nb 3 Sn SRF cavities, indicating possible effects of GB segregation on the quality (Q 0 ) factor of Nb 3 Sn SRF cavities. Our results suggest that the chemistry of GBs of Nb 3 Sn coatings for SRF cavities can be controlled by grain-boundary engineering, and can be used to direct fabrication of high-quality Nb 3 Sn coatings for SRF cavities.

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Direct observation of Nb₃Sn lattice deformation by high-energy x-ray diffraction in internal-tin wires subject to mechanical loads at 4.2 K

Muzzi

Corato

Corte

et al. 2012

Supercond. Sci. Technol.

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With the aim of clarifying the relationship between lattice deformations and superconducting properties of Nb3Sn technological wires we have carried out high-energy x-ray diffraction experiments at the European Synchrotron Radiation Facility (ESRF) in Grenoble on individual samples of multi-filamentary internal-tin-type Nb3Sn wires. In particular, a test probe developed at the University of Geneva allowed us to perform these experiments at 4.2 K, while applying an axial tensile load to the specimen. In this way, the lattice parameter values of all the constituents (Nb3Sn, Nb, Cu) were determined, in both the parallel and orthogonal directions with respect to the applied load axis, as a function of the applied strain. The experiments were performed on industrial wires, which were reinforced by a stainless steel outer tube, applied before the Nb3Sn reaction heat treatment, in order to evaluate the effect of an additional pre-compression strain. The relation between the microscopically determined crystalline lattice deformations and the measured applied strain is discussed as a basis for the analysis of the superconducting performances of Nb3Sn wires subject to mechanical loads.

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Correlation Between the Number of Displacements Per Atom and After High-Energy Irradiations of Nb₃Sn Wires for the HL-LHC

Spina

Scheuerlein

Richter

et al. 2016

IEEE Trans. Appl. Supercond.

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Microwave measurements of the high magnetic field vortex motion pinning parameters in Nb₃Sn

Alimenti

Pompeo

Torokhtii

et al. 2020

Supercond. Sci. Technol.

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The high frequency vortex motion in Nb3Sn was analyzed in this work up to 12 T. We used a dielectric loaded resonator tuned at 15 GHz to evaluate the surface impedance Z of a Nb3Sn bulk sample (24.8 at.%Sn). From the field induced variation of Z, the high frequency vortex parameters (the pinning constant k p , the depinning frequency ν p and the flux flow resistivity ρ ff ) were obtained over a large temperature and field range; their field and temperature dependencies were analyzed. Comparison with other superconducting materials shows that high frequency applications in strong magnetic fields are also feasible with Nb3Sn. In the present work, we report the first measurements about the microwave response in Nb3Sn in strong magnetic fields.

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Variation ofT_c, lattice parameter and atomic ordering in Nb₃Sn platelets irradiated with 12 MeV protons: correlation with the number of induced Frenkel defects

Flükiger

Spina

Cerutti

et al. 2017

Supercond. Sci. Technol.

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Nb3Sn platelets with thicknesses between 0.12 and 0.20 mm produced by a high isostatic pressure process at 1250 °C were irradiated at 300 K with 12 MeV protons. The effects of irradiation on the lattice parameter a, the atomic order parameter S and the transition temperature Tc were measured as a function of proton fluence. In view of the presence of multiple energy radiation sources in future accelerators, the present proton data are compared with neutron irradiation data from the literature. The fluences for both types of radiation were replaced by the dpa number, the ‘displacements per atom’, calculated using the FLUKA code, which is proportional to the number of radiation induced Frenkel defects. It was found that the variation of both a and S for Nb3Sn after proton and neutron irradiation as a function of dpa fall almost on the same curve, in analogy to the recently reported correlation between Tc and the dpa number. By a simultaneous irradiation of two adjacent thin Nb3Sn platelets, we have shown that this correlation is not only valid for the state of ‘steady energy loss’ (protons traveling through the first platelet) but also for the state of higher damage at the Bragg peak (second platelet). It follows that the number of radiation induced Frenkel defects in the A15 grains, calculated via the dpa number, can be considered as a ‘universal’ parameter, allowing the calculation of the variation of Tc, a and S of Nb3Sn under the effect of multiple high energy radiation sources, as in future superconducting accelerators.

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Tiziana Spina

Grain-boundary structure and segregation in Nb3Sn coatings on Nb for high-performance superconducting radiofrequency cavity applications

Direct observation of Nb₃Sn lattice deformation by high-energy x-ray diffraction in internal-tin wires subject to mechanical loads at 4.2 K

Correlation Between the Number of Displacements Per Atom and After High-Energy Irradiations of Nb₃Sn Wires for the HL-LHC

Microwave measurements of the high magnetic field vortex motion pinning parameters in Nb₃Sn

Variation ofT_c, lattice parameter and atomic ordering in Nb₃Sn platelets irradiated with 12 MeV protons: correlation with the number of induced Frenkel defects

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Tiziana Spina

Grain-boundary structure and segregation in Nb3Sn coatings on Nb for high-performance superconducting radiofrequency cavity applications

Direct observation of Nb3Sn lattice deformation by high-energy x-ray diffraction in internal-tin wires subject to mechanical loads at 4.2 K

Correlation Between the Number of Displacements Per Atom and After High-Energy Irradiations of Nb3Sn Wires for the HL-LHC

Microwave measurements of the high magnetic field vortex motion pinning parameters in Nb3Sn

Variation ofTc, lattice parameter and atomic ordering in Nb3Sn platelets irradiated with 12 MeV protons: correlation with the number of induced Frenkel defects

Contact Info

Product

Resources

About

Direct observation of Nb₃Sn lattice deformation by high-energy x-ray diffraction in internal-tin wires subject to mechanical loads at 4.2 K

Correlation Between the Number of Displacements Per Atom and After High-Energy Irradiations of Nb₃Sn Wires for the HL-LHC

Microwave measurements of the high magnetic field vortex motion pinning parameters in Nb₃Sn

Variation ofT_c, lattice parameter and atomic ordering in Nb₃Sn platelets irradiated with 12 MeV protons: correlation with the number of induced Frenkel defects