Template‐Free Growth of High‐Temperature Superconductor Nanowires

Jason Potticary; Emily J. Luke; Ektor M. S. Christodoulou; Rowena Davies; Sorrel Haughton; Cheryl Feuillet-Palma; Eliana Recoba-Pawlowski; Brigitte Leridon; Sarah Griffin; Simon R. Hall

doi:10.1002/sstr.202300087

Template‐Free Growth of High‐Temperature Superconductor Nanowires

Jason Potticary, Emily J. Luke, Ektor M. S. Christodoulou, Rowena Davies, Sorrel Haughton, Cheryl Feuillet-Palma, Eliana Recoba-Pawlowski, Brigitte Leridon, Sarah Griffin, Simon R. Hall^*

^*Corresponding author for this work

Chemistry

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Abstract

As devices become ever smaller and more efficient, the crystallochemically controlled synthesis of high‐performance materials that comprise their core has attracted enormous attention. Integration of complex functional materials into the next generation of electronic devices will require exquisite control of anisotropic form, either as nanotubes, nanotapes, or nanowires, yet the easy preparation of abundant quantities of them remains stubbornly challenging. Herein, a template‐free, flux‐mediated growth of vast quantities of three compositions of phase‐pure, high‐temperature superconductor nanowires, including for the first time, nanowires of the technologically important quinternary superconductor Bi2Sr2CaCu2O8+x (B2212) is demonstrated. The results of this work may provide an opportunity to investigate the physics and chemistry of highly anisotropic superconductor nanowires and enable their incorporation into nanoelectronics and energy generation systems.

Original language	English
Article number	2300087
Number of pages	7
Journal	Small Structures
Early online date	16 Jul 2023
DOIs	https://doi.org/10.1002/sstr.202300087
Publication status	E-pub ahead of print - 16 Jul 2023

Keywords

synthesis
superconductors
metal oxides
nanowires
flux growth

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Cite this

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title = "Template‐Free Growth of High‐Temperature Superconductor Nanowires",

abstract = "As devices become ever smaller and more efficient, the crystallochemically controlled synthesis of high‐performance materials that comprise their core has attracted enormous attention. Integration of complex functional materials into the next generation of electronic devices will require exquisite control of anisotropic form, either as nanotubes, nanotapes, or nanowires, yet the easy preparation of abundant quantities of them remains stubbornly challenging. Herein, a template‐free, flux‐mediated growth of vast quantities of three compositions of phase‐pure, high‐temperature superconductor nanowires, including for the first time, nanowires of the technologically important quinternary superconductor Bi2Sr2CaCu2O8+x (B2212) is demonstrated. The results of this work may provide an opportunity to investigate the physics and chemistry of highly anisotropic superconductor nanowires and enable their incorporation into nanoelectronics and energy generation systems.",

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author = "Jason Potticary and Luke, {Emily J.} and Christodoulou, {Ektor M. S.} and Rowena Davies and Sorrel Haughton and Cheryl Feuillet-Palma and Eliana Recoba-Pawlowski and Brigitte Leridon and Sarah Griffin and Hall, {Simon R.}",

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doi = "10.1002/sstr.202300087",

language = "English",

journal = "Small Structures",

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T1 - Template‐Free Growth of High‐Temperature Superconductor Nanowires

AU - Potticary, Jason

AU - Luke, Emily J.

AU - Christodoulou, Ektor M. S.

AU - Davies, Rowena

AU - Haughton, Sorrel

AU - Feuillet-Palma, Cheryl

AU - Recoba-Pawlowski, Eliana

AU - Leridon, Brigitte

AU - Griffin, Sarah

AU - Hall, Simon R.

PY - 2023/7/16

Y1 - 2023/7/16

N2 - As devices become ever smaller and more efficient, the crystallochemically controlled synthesis of high‐performance materials that comprise their core has attracted enormous attention. Integration of complex functional materials into the next generation of electronic devices will require exquisite control of anisotropic form, either as nanotubes, nanotapes, or nanowires, yet the easy preparation of abundant quantities of them remains stubbornly challenging. Herein, a template‐free, flux‐mediated growth of vast quantities of three compositions of phase‐pure, high‐temperature superconductor nanowires, including for the first time, nanowires of the technologically important quinternary superconductor Bi2Sr2CaCu2O8+x (B2212) is demonstrated. The results of this work may provide an opportunity to investigate the physics and chemistry of highly anisotropic superconductor nanowires and enable their incorporation into nanoelectronics and energy generation systems.

AB - As devices become ever smaller and more efficient, the crystallochemically controlled synthesis of high‐performance materials that comprise their core has attracted enormous attention. Integration of complex functional materials into the next generation of electronic devices will require exquisite control of anisotropic form, either as nanotubes, nanotapes, or nanowires, yet the easy preparation of abundant quantities of them remains stubbornly challenging. Herein, a template‐free, flux‐mediated growth of vast quantities of three compositions of phase‐pure, high‐temperature superconductor nanowires, including for the first time, nanowires of the technologically important quinternary superconductor Bi2Sr2CaCu2O8+x (B2212) is demonstrated. The results of this work may provide an opportunity to investigate the physics and chemistry of highly anisotropic superconductor nanowires and enable their incorporation into nanoelectronics and energy generation systems.

KW - synthesis

KW - superconductors

KW - metal oxides

KW - nanowires

KW - flux growth

U2 - 10.1002/sstr.202300087

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SN - 2688-4062

JO - Small Structures

JF - Small Structures

M1 - 2300087

ER -

Template‐Free Growth of High‐Temperature Superconductor Nanowires

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Keywords

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