Engineered Pinning Landscapes for Enhanced 2G Coil Wire

Martin W. Rupich; Srivatsan Sathyamurthy; Steven Fleshler; Qiang Li; Vyacheslav Solovyov; Toshinori Ozaki; Ulrich Welp; Wai Kwong Kwok; Maxime Leroux; Alexei E. Koshelev; Dean J. Miller; Karen Kihlstrom; Leonardo Civale; Serena Eley; Asghar Kayani

doi:10.1109/TASC.2016.2542270

Engineered Pinning Landscapes for Enhanced 2G Coil Wire

Martin W. Rupich
, Srivatsan Sathyamurthy
, Steven Fleshler
, Qiang Li
, Vyacheslav Solovyov
, Toshinori Ozaki
, Ulrich Welp
, Wai Kwong Kwok
, Maxime Leroux
, Alexei E. Koshelev
, Dean J. Miller
, Karen Kihlstrom
, Leonardo Civale
, Serena Eley
, Asghar Kayani

Stony Brook University

American Superconductor Corporation
Brookhaven National Laboratory
Argonne National Laboratory
Los Alamos National Laboratory
Western Michigan University

Research output: Contribution to journal › Article › peer-review

48 Scopus citations

Abstract

We demonstrate a twofold increase in the in-field critical current of AMSC's standard 2G coil wire by irradiation with 18-MeV Au ions. The optimum pinning enhancement is achieved with a dose of 6 × 10¹¹ Au ions/cm². Although the 77 K, self-field critical current is reduced by about 35%, the in-field critical current (H//c) shows a significant enhancement between 4 and 50 K in fields > 1 T. The process was used for the roll-to-roll irradiation of AMSC's standard 46-mm-wide production coated conductor strips, which were further processed into standard copper laminated coil wire. The long-length wires show the same enhancement as attained with short static irradiated samples. The roll-to-roll irradiation process can be incorporated in the standard 2G wire manufacturing, with no modifications to the current process. The enhanced performance of the wire will benefit rotating machine and magnet applications.

Original language	English
Article number	7433971
Journal	IEEE Transactions on Applied Superconductivity
Volume	26
Issue number	3
DOIs	https://doi.org/10.1109/TASC.2016.2542270
State	Published - Apr 2016

Keywords

Critical current density
flux pinning
high-temperature superconductors
irradiation
roll-to-roll processing

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10.1109/TASC.2016.2542270

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Rupich, M. W., Sathyamurthy, S., Fleshler, S., Li, Q., Solovyov, V., Ozaki, T., Welp, U., Kwok, W. K., Leroux, M., Koshelev, A. E., Miller, D. J., Kihlstrom, K., Civale, L., Eley, S., & Kayani, A. (2016). Engineered Pinning Landscapes for Enhanced 2G Coil Wire. IEEE Transactions on Applied Superconductivity, 26(3), Article 7433971. https://doi.org/10.1109/TASC.2016.2542270

@article{1d0d9c1232c64103bf91864ffdc4e105,

title = "Engineered Pinning Landscapes for Enhanced 2G Coil Wire",

abstract = "We demonstrate a twofold increase in the in-field critical current of AMSC's standard 2G coil wire by irradiation with 18-MeV Au ions. The optimum pinning enhancement is achieved with a dose of 6 × 1011 Au ions/cm2. Although the 77 K, self-field critical current is reduced by about 35\%, the in-field critical current (H//c) shows a significant enhancement between 4 and 50 K in fields > 1 T. The process was used for the roll-to-roll irradiation of AMSC's standard 46-mm-wide production coated conductor strips, which were further processed into standard copper laminated coil wire. The long-length wires show the same enhancement as attained with short static irradiated samples. The roll-to-roll irradiation process can be incorporated in the standard 2G wire manufacturing, with no modifications to the current process. The enhanced performance of the wire will benefit rotating machine and magnet applications.",

keywords = "Critical current density, flux pinning, high-temperature superconductors, irradiation, roll-to-roll processing",

author = "Rupich, \{Martin W.\} and Srivatsan Sathyamurthy and Steven Fleshler and Qiang Li and Vyacheslav Solovyov and Toshinori Ozaki and Ulrich Welp and Kwok, \{Wai Kwong\} and Maxime Leroux and Koshelev, \{Alexei E.\} and Miller, \{Dean J.\} and Karen Kihlstrom and Leonardo Civale and Serena Eley and Asghar Kayani",

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AU - Rupich, Martin W.

AU - Sathyamurthy, Srivatsan

AU - Fleshler, Steven

AU - Li, Qiang

AU - Solovyov, Vyacheslav

AU - Ozaki, Toshinori

AU - Welp, Ulrich

AU - Kwok, Wai Kwong

AU - Leroux, Maxime

AU - Koshelev, Alexei E.

AU - Miller, Dean J.

AU - Kihlstrom, Karen

AU - Civale, Leonardo

AU - Eley, Serena

AU - Kayani, Asghar

PY - 2016/4

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N2 - We demonstrate a twofold increase in the in-field critical current of AMSC's standard 2G coil wire by irradiation with 18-MeV Au ions. The optimum pinning enhancement is achieved with a dose of 6 × 1011 Au ions/cm2. Although the 77 K, self-field critical current is reduced by about 35%, the in-field critical current (H//c) shows a significant enhancement between 4 and 50 K in fields > 1 T. The process was used for the roll-to-roll irradiation of AMSC's standard 46-mm-wide production coated conductor strips, which were further processed into standard copper laminated coil wire. The long-length wires show the same enhancement as attained with short static irradiated samples. The roll-to-roll irradiation process can be incorporated in the standard 2G wire manufacturing, with no modifications to the current process. The enhanced performance of the wire will benefit rotating machine and magnet applications.

AB - We demonstrate a twofold increase in the in-field critical current of AMSC's standard 2G coil wire by irradiation with 18-MeV Au ions. The optimum pinning enhancement is achieved with a dose of 6 × 1011 Au ions/cm2. Although the 77 K, self-field critical current is reduced by about 35%, the in-field critical current (H//c) shows a significant enhancement between 4 and 50 K in fields > 1 T. The process was used for the roll-to-roll irradiation of AMSC's standard 46-mm-wide production coated conductor strips, which were further processed into standard copper laminated coil wire. The long-length wires show the same enhancement as attained with short static irradiated samples. The roll-to-roll irradiation process can be incorporated in the standard 2G wire manufacturing, with no modifications to the current process. The enhanced performance of the wire will benefit rotating machine and magnet applications.

KW - Critical current density

KW - flux pinning

KW - high-temperature superconductors

KW - irradiation

KW - roll-to-roll processing

UR - https://www.scopus.com/pages/publications/84964330033

U2 - 10.1109/TASC.2016.2542270

DO - 10.1109/TASC.2016.2542270

M3 - Article

SN - 1051-8223

VL - 26

JO - IEEE Transactions on Applied Superconductivity

JF - IEEE Transactions on Applied Superconductivity

IS - 3

M1 - 7433971

ER -

Engineered Pinning Landscapes for Enhanced 2G Coil Wire

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Keywords

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