Microstructure evolution of NbTiTa composite after extrusions

Quan Ma; Zili Chen; Xianghong Liu; Lian Zhou; Xiaozu Wu; Yafeng Lu

Microstructure evolution of NbTiTa composite after extrusions

Quan Ma, Zili Chen, Xianghong Liu, Lian Zhou, Xiaozu Wu, Yafeng Lu

School of Materials Sience and Engineering

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

1 Scopus citations

Abstract

Using sheets of Nb, Ti and Ta as starting material, NbTiTa superconducting filaments were prepared by extrusion and drawing. The microstructure evolution of the composite after extrusions and the diffusion among Nb, Ti and Ta in the composite were studied. It is found that a large number of crystal defects and the temperature increment appeared, which is caused by the large plastic deformation during hot extrusions, as a result, the Nb, Ti, and Ta sheets diffused each other heavily. The non-superconducting Ti-rich area and superconducting Nb-rich area and Ta-rich area formed during extrusions. The volume percentage of Ti-rich area exceeded 30%, and the transects of Ti-rich area, Nb-rich area, and Ta-rich area all evolved into ribbon-like shape in extrusions and drawing.

Original language	English
Pages (from-to)	105-107
Number of pages	3
Journal	Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering
Volume	37
Issue number	1
State	Published - Jan 2008

Keywords

APC
NbTiTa
Temperature superconductor

Cite this

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abstract = "Using sheets of Nb, Ti and Ta as starting material, NbTiTa superconducting filaments were prepared by extrusion and drawing. The microstructure evolution of the composite after extrusions and the diffusion among Nb, Ti and Ta in the composite were studied. It is found that a large number of crystal defects and the temperature increment appeared, which is caused by the large plastic deformation during hot extrusions, as a result, the Nb, Ti, and Ta sheets diffused each other heavily. The non-superconducting Ti-rich area and superconducting Nb-rich area and Ta-rich area formed during extrusions. The volume percentage of Ti-rich area exceeded 30%, and the transects of Ti-rich area, Nb-rich area, and Ta-rich area all evolved into ribbon-like shape in extrusions and drawing.",

keywords = "APC, NbTiTa, Temperature superconductor",

author = "Quan Ma and Zili Chen and Xianghong Liu and Lian Zhou and Xiaozu Wu and Yafeng Lu",

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TY - JOUR

T1 - Microstructure evolution of NbTiTa composite after extrusions

AU - Ma, Quan

AU - Chen, Zili

AU - Liu, Xianghong

AU - Zhou, Lian

AU - Wu, Xiaozu

AU - Lu, Yafeng

PY - 2008/1

Y1 - 2008/1

N2 - Using sheets of Nb, Ti and Ta as starting material, NbTiTa superconducting filaments were prepared by extrusion and drawing. The microstructure evolution of the composite after extrusions and the diffusion among Nb, Ti and Ta in the composite were studied. It is found that a large number of crystal defects and the temperature increment appeared, which is caused by the large plastic deformation during hot extrusions, as a result, the Nb, Ti, and Ta sheets diffused each other heavily. The non-superconducting Ti-rich area and superconducting Nb-rich area and Ta-rich area formed during extrusions. The volume percentage of Ti-rich area exceeded 30%, and the transects of Ti-rich area, Nb-rich area, and Ta-rich area all evolved into ribbon-like shape in extrusions and drawing.

AB - Using sheets of Nb, Ti and Ta as starting material, NbTiTa superconducting filaments were prepared by extrusion and drawing. The microstructure evolution of the composite after extrusions and the diffusion among Nb, Ti and Ta in the composite were studied. It is found that a large number of crystal defects and the temperature increment appeared, which is caused by the large plastic deformation during hot extrusions, as a result, the Nb, Ti, and Ta sheets diffused each other heavily. The non-superconducting Ti-rich area and superconducting Nb-rich area and Ta-rich area formed during extrusions. The volume percentage of Ti-rich area exceeded 30%, and the transects of Ti-rich area, Nb-rich area, and Ta-rich area all evolved into ribbon-like shape in extrusions and drawing.

KW - APC

KW - NbTiTa

KW - Temperature superconductor

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JO - Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering

JF - Xiyou Jinshu Cailiao Yu Gongcheng/Rare Metal Materials and Engineering

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Microstructure evolution of NbTiTa composite after extrusions

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