NDLI: Development of High Performance <formula formulatype=inline> <tex>${rm Nb}_{3}{rm Sn}$</tex></formula> Conductor for Fusion and Accelerator Applications

Content Provider	IEEE Xplore Digital Library
Author	Taeyoung Pyon Somerkoski, J. Kanithi, H. Karlemo, B. Holm, M.
Copyright Year	2002
Abstract	While the highest field performance is a primary goal of the conductor in the next generation of particle accelerators, emphasis has been focused mainly on the increase in current carrying capacity. The conductor needed for fusion application, however, requires much lower magnetization limit along with a critical current as high as possible. The upgraded strand specifications for the International Thermonuclear Experimental Reactor (ITER) and particle accelerator applications require further improvement of current density at little expense of ac loss or effective filament diameter. A conductor designed to meet such requirements has been fabricated. The effect of heat treatment condition on its properties was investigated to develop an optimized reaction condition. Significant efforts have been made to explore the sub-element design and configuration of the strand to ensure minimum hysteresis of the wire. An attempt was also made to scale up the restack assembly unit for mass production.
Sponsorship	Council on Superconductivity Appl. Superconductivity Conference Inc MIT
Starting Page	2568
Ending Page	2571
Page Count	4
File Size	1395746
File Format	PDF
ISSN	10518223
Volume Number	17
Issue Number	2
Language	English
Publisher	Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Publisher Date	2007-06-01
Publisher Place	U.S.A.
Access Restriction	One Nation One Subscription (ONOS)
Rights Holder	Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subject Keyword	Niobium Conductors Linear particle accelerator Magnetization Critical current Inductors Current density Fusion reactor design Heat treatment Hysteresis tokamak Accelerator fusion hysteresis loss internal-tin processed ${\rm Nb}_{3}{\rm Sn}$ superconducting wires
Content Type	Text
Resource Type	Article
Subject	Condensed Matter Physics Electronic, Optical and Magnetic Materials Electrical and Electronic Engineering

Sl.	Authority	Responsibilities	Communication Details
1	Ministry of Education (GoI), Department of Higher Education	Sanctioning Authority	https://www.education.gov.in/ict-initiatives
2	Indian Institute of Technology Kharagpur	Host Institute of the Project: The host institute of the project is responsible for providing infrastructure support and hosting the project	https://www.iitkgp.ac.in
3	National Digital Library of India Office, Indian Institute of Technology Kharagpur	The administrative and infrastructural headquarters of the project	Dr. B. Sutradhar bsutra@ndl.gov.in
4	Project PI / Joint PI	Principal Investigator and Joint Principal Investigators of the project	Dr. B. Sutradhar bsutra@ndl.gov.in Prof. Saswat Chakrabarti will be added soon
5	Website/Portal (Helpdesk)	Queries regarding NDLI and its services	support@ndl.gov.in
6	Contents and Copyright Issues	Queries related to content curation and copyright issues	content@ndl.gov.in
7	National Digital Library of India Club (NDLI Club)	Queries related to NDLI Club formation, support, user awareness program, seminar/symposium, collaboration, social media, promotion, and outreach	clubsupport@ndl.gov.in
8	Digital Preservation Centre (DPC)	Assistance with digitizing and archiving copyright-free printed books	dpc@ndl.gov.in
9	IDR Setup or Support	Queries related to establishment and support of Institutional Digital Repository (IDR) and IDR workshops	idr@ndl.gov.in

Development of ${rm Nb}_{3}{rm Sn}$ Internal Tin Strands With Enhanced Current Capacity and Improved Mechanical Properties

Investigation of ${rm Nb}_{3}{rm Sn}$ Strand for ITER by Bronze Route

Investigation of Magnetization Behavior of ${rm Nb}_{3}{rm Sn}$ Wires for the Next European Dipole (NED) Activity

Development of Internal Tin ${hbox{Nb}}_{3}{hbox{Sn}}$ Conductor for Fusion and Particle Accelerator Applications

The effect of Mn additions on the hysteresis loss and critical current density of power-metallurgy processed superconducting Nb/sub 3/Sn wires

Investigation of Superconducting Properties of ${rm Nb}_{3}{rm Sn}$ Strands by Internal Tin Process for ITER

Evaluation of the Critical Current Density of Multifilamentary ${rm Nb}_{3}{rm Sn}$ Wires From Magnetization Measurements

Investigation on the Effect of Ta Additions on $J_{c}$ and $n$ of $({rm Nb},{rm Ti})_{3}{rm Sn}$ Bronze Processed Multifilamentary Wires at High Magnetic Fields

Characterization of ${rm Nb}_{3}{rm Al}$ Strands Subjected to an Axial-Strain for a Fusion DEMO Reactor

Development of High Performance ${rm Nb}_{3}{rm Sn}$ Conductor for Fusion and Accelerator Applications

Similar Documents

Development of ${rm Nb}_{3}{rm Sn}$ Internal Tin Strands With Enhanced Current Capacity and Improved Mechanical Properties

Investigation of ${rm Nb}_{3}{rm Sn}$ Strand for ITER by Bronze Route

Investigation of Magnetization Behavior of ${rm Nb}_{3}{rm Sn}$ Wires for the Next European Dipole (NED) Activity

Development of Internal Tin ${hbox{Nb}}_{3}{hbox{Sn}}$ Conductor for Fusion and Particle Accelerator Applications

The effect of Mn additions on the hysteresis loss and critical current density of power-metallurgy processed superconducting Nb/sub 3/Sn wires

Investigation of Superconducting Properties of ${rm Nb}_{3}{rm Sn}$ Strands by Internal Tin Process for ITER

Evaluation of the Critical Current Density of Multifilamentary ${rm Nb}_{3}{rm Sn}$ Wires From Magnetization Measurements

Investigation on the Effect of Ta Additions on $J_{c}$ and $n$ of $({rm Nb},{rm Ti})_{3}{rm Sn}$ Bronze Processed Multifilamentary Wires at High Magnetic Fields

Characterization of ${rm Nb}_{3}{rm Al}$ Strands Subjected to an Axial-Strain for a Fusion DEMO Reactor

Development of High Performance ${rm Nb}_{3}{rm Sn}$ Conductor for Fusion and Accelerator Applications