Chemical Emulation of Radiation Pinning Center Geometries in High Temperature Superconductors

Abstract

Discovery of sub-micron size deposits of (U, Zr, Nd, Ba, 0) in Nd123 enabled application of the U/n method to Nd123, resulting in world record J(sub c). Discovery of an entire class of 200-400 nm size, double perovskite pinning centers, (A,B)REBa(sub 2)O(sub 6), led to ^20 new chemical "point" pinning centers, and enabled replacement of successful but expensive and radioactive (U(sub 0.6)Pt(sub 0.4))REBa(sub 2)O(sub 6) pinning centers with inexpensive, non-radioactive (W(sub 0.5),Zr(sub 0.5()REBa(sub 2)O(sub 6). Additional studies proved that the parent compound used for additives strongly effect the critical parameter of pinning center size. Theoretical studies of the cause of decreasing J(sub c), when large ion fluences are used to induce pinning, led to postulating a new class of pinning centers based on multiple-in-line-damage (MILD). Achievement of self-assembling chemical columnar structures in YBCO proved the feasibility of our ultimate goal of producing such chemical pinning centers in small enough diameter to play the role of ideal pinning centers.

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Document Details

Document Type
Technical Report
Publication Date
Jul 31, 2004
Accession Number
ADA425418

Entities

People

  • Roy Weinstein

Organizations

  • University of Houston

Tags

Communities of Interest

  • Advanced Electronics
  • Autonomy
  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Chemistry
  • Diameters
  • Elements
  • Geometry
  • High Temperature
  • High Temperature Superconductors
  • Magnetic Fields
  • Materials
  • Neutron Bombardment
  • Neutrons
  • Perovskites
  • Radiation
  • Students
  • Superconductivity
  • Superconductors
  • Thermal Neutrons
  • Uranium Compounds

Fields of Study

  • Physics

Readers

  • Analytical Mechanics
  • Superconducting Magnet Technology
  • Systems Analysis and Design