Optimization of Nb<sub>3</sub>Sn and MgB<sub>2</sub>wires

Flükiger, R.; Senatore, Carmine; Cesaretti, Marco; Buta, F.; Uglietti, D.; Seeber, B.

doi:10.1088/0953-2048/21/5/054015

Cited by 35 publications

(47 citation statements)

References 35 publications

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“…This procedure has been successfully used in the case of wires, polycrystalline samples, and crystals. [70][71][72][73] However, if pinning is ruled only by defects whose dimensions are smaller than the intervortex distance, it is expected J 1/2 c ∝ (1 − h). 67 In this case, H irr may be determined by doing a linear extrapolation down to zero of the J These results indicate that, for the single crystal sample B, the pinning mechanisms are ruled by defects whose dimensions are smaller that the intervortex distance in the investigated field range and as a consequence, the most appropriate procedure for determining H irr (T ) is from the J 1/2 c vs H curve.…”

Section: A Vortex Pinning Propertiesmentioning

confidence: 99%

Temperature and time scaling of the peak-effect vortex configuration in FeTe0.7Se0.3

et al. 2012

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An extensive study of the magnetic properties of FeTe 0.7 Se 0.3 crystals in the superconducting state is presented. We show that weak collective pinning, originating from spatial variations of the charge carrier mean free path (δl pinning), rules in this superconductor. Our results are compatible with the nanoscale phase separation observed on this compound and indicate that in spite of the chemical inhomogeneity, spatial fluctuations of the critical temperature are not important for pinning. A power-law dependence of the magnetization vs time, generally interpreted as the signature of a single-vortex creep regime, is observed in magnetic fields up to 8 T. For magnetic fields applied along the c axis of the crystal, the magnetization curves exhibit a clear peak effect whose position shifts when varying the temperature, following the same dependence as observed in YBa 2 Cu 3 O 7−δ . The time and temperature dependence of the peak position has been investigated. We observe that the occurrence of the peak at a given magnetic field determines a specific vortex configuration that is independent on the temperature. This result indicates that the influence of the temperature on the vortex-vortex and vortex-defect interactions leading to the peak effect in FeTe 0.7 Se 0.3 is negligible in the explored range of temperatures.

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Section: A Vortex Pinning Propertiesmentioning

confidence: 99%

Temperature and time scaling of the peak-effect vortex configuration in FeTe0.7Se0.3

et al. 2012

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“…The difference is due to the fact that Ta replaces Nb and Ti replaces Sn in the Nb 3 Sn lattice (suggested in Ref. 105 and confirmed by Ref. 106).…”

Section: Bottura and A Godekementioning

confidence: 83%

Superconducting Materials and Conductors: Fabrication and Limiting Parameters

Bottura

Godeke

2013

Reviews of Accelerator Science and Technology

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Superconductivity is the technology that enabled the construction of the most recent generation of high-energy particle accelerators, the largest scientific instruments ever built. In this review we trace the evolution of superconducting materials for particle accelerator magnets, from the first steps in the late 1960s, through the rise and glory of Nb-Ti in the 1970s, till the 2010s, and the promises of Nb 3 Sn for the 2020s. We conclude with a perspective on the opportunities for high-temperature superconductors (HTSs). Many such reviews have been written in the past, as witnessed by the long list of references provided. In this review we put particular emphasis on the practical aspects of wire and tape manufacturing, cabling, engineering performance, and potential for use in accelerator magnets, while leaving in the background matters such as the physics of superconductivity and fundamental material issues.

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“…In experiments by Goldacker et al [134,135], it was observed that the martensitic transformation in stoichiometric Nb 3 Sn could be prevented through various additions, including tantalum, titanium, nickel, gallium, and hydrogen. The martensitic transformation was completely suppressed in samples with 0.6 at.% H, 2.8 at.% Ta, 1.3 at.% Ti, and 1 at.% Ni, with normal state resistivities of 37 µΩcm, 29 µΩcm, 33 µΩcm, and 30 µΩcm, respectively.…”

Section: Literature On the Martensitic Transformationmentioning

confidence: 99%

An experimental and computational study of srain sensitivity in superconducting Nb3Sn

Mentink

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This work is the result of efforts by many people, both in a professional and a personal sense. During my time in Berkeley I had the opportunity to work with friendly and supportive people who were pushing back scientific boundaries, regarding the limits of superconducting high field technology. It is an odd but good experience to read papers from various authors detailing one scientific breakthrough or another, and then to meet them in person. Being a multi-cultural hub, Berkeley also allowed me to meet and become friends with people from all corners of this planet.Along the way, people have been instrumental in making this research happen. At LBNL, Jonathan Slack, Reuben Mendelsberg, and Andre Anders allowed me to use their lab for a rather extended period of time thus allowing for the fabrication of thin films, and have helped in various other ways along the years. The people at Ohio State University have helped by repeatedly performing heat capacity measurements on Nb 3 Sn bulk samples which were kindly supplied by Wilfried Goldacker of the Karlsruhe Institute of Technology. In particular I would like to thank Mike Susner of the Ohio State University, who came to the lab in the weekends just to make sure my samples would get measured. John Bonevich of the National Institute of Science and Technology was kind enough to perform characterization work on some of the Nb-Sn thin films we made, which included the STEM image on the cover. A lot of the experimental work was made possible with software and hardware designed at the University of Twente (such as VI by Bennie ten Haken), and I have gotten useful recommendations and assistance along the way, such as the advice on thin film fabrication from Frank Roesthuis. Professors Marcel ter Brake, Herman ten Kate, David Larbalestier, and Frances Hellman were kind enough to write letters of recommendation which contributed to getting the CSC student fellowship award. Vladimir Kresin of LBNL was kind enough to answer various questions related to the microscopic properties of Nb 3 Sn and comment on the description of microscopic theory in this thesis.Shane Cybart and Stephen Wu have assisted Edwin Dollekamp and myself in attempting to do some very fancy experiments. Edwin, from the University of Twente, took on a complicated research topic and I was impressed with how far he managed to get in that work, and Shane and Stephen invested time in the evenings and weekends to make it happen. Professor Orlandos previous investigations of Nb 3 Sn were an inspiration for some of the work described in this thesis, and he was kind enough to answer questions by email and over the phone. Derek Stewart of the Cornell NanoScale Science and Technology Facility helped me to get familiar with density functional theory calculations and computing clusters and made the suggestion of using Quantum Espresso ab-initio software. Robert Ryne and Steve Gourlay of LBNL helped me getting access to sizeable supercomputing resources at NERSC which were needed for this research.My friends and family st...

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Optimization of Nb₃Sn and MgB₂wires

Cited by 35 publications

References 35 publications

Temperature and time scaling of the peak-effect vortex configuration in FeTe0.7Se0.3

Temperature and time scaling of the peak-effect vortex configuration in FeTe0.7Se0.3

Superconducting Materials and Conductors: Fabrication and Limiting Parameters

An experimental and computational study of srain sensitivity in superconducting Nb3Sn

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Optimization of Nb3Sn and MgB2wires

Cited by 35 publications

References 35 publications

Temperature and time scaling of the peak-effect vortex configuration in FeTe0.7Se0.3

Temperature and time scaling of the peak-effect vortex configuration in FeTe0.7Se0.3

Superconducting Materials and Conductors: Fabrication and Limiting Parameters

An experimental and computational study of srain sensitivity in superconducting Nb3Sn

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Product

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Optimization of Nb₃Sn and MgB₂wires