مرکز منطقه ای اطلاع رساني علوم و فناوري - Nanostructural Defects and Critical Current Densities in High-Quality <inline-formula> <img src="/images/tex/24541.gif" alt="\\hbox {Bi}_{2}\\hbox {Sr}_{2}\\hbox {CaCu}_{2}\\hbox {O}_{8+{\\rm X}} "> </inline-formula> Epitaxial Thin Films Prepared by MOCVD

DocumentCode :

38384

Title :

Nanostructural Defects and Critical Current Densities in High-Quality $\\hbox {Bi}_{2}\\hbox {Sr}_{2}\\hbox {CaCu}_{2}\\hbox {O}_{8+{\\rm X}}$ Epitaxial Thin Films Prepared by MOCVD

Author :

Yamasaki, Hirofumi ; Endo, Kazuhiro

Author_Institution :

Nat. Inst. of Adv. Ind. Sci. & Technol. (AIST), Tsukuba, Japan

Volume :

Issue :

fYear :

2015

fDate :

Jun-15

Firstpage :

Lastpage :

Abstract :

Nanostructural defects were investigated by transmission electron microscopy in c-axis-oriented epitaxial Bi₂Sr₂CaCu₂O_8+X (Bi2212) thin films with high T_c(R = 0) ≥ 83 K and high transport critical current density ofJ_c >10¹⁰ A/m² at 10 K. We observed misfit dislocations at twin boundaries, dislocations associated with stacking faults parallel to the a-b plane, and antiphase boundaries. We compared the magnetic-field dependent J_c values at various temperatures in two Bi2212 films. About 110-nm-thick film A showed lower J_c than ~280-nm-thick film B at low temperatures (≤ 20 K) or in low magnetic fields (≤ 0.1 T). However, the J_c of film B decreased more rapidly in high magnetic fields, leading to a crossover of the two J_c-B curves at temperatures of 30 K and above. This is probably because film B contained a higher density of antiphase boundaries, which caused stronger pinning and higher J_c values at low temperatures but may have caused enhanced thermally activated motion of pancake vortices that eventually resulted in lower Jc values in high magnetic fields at moderate temperatures.

Keywords :

MOCVD; bismuth compounds; calcium compounds; critical current density (superconductivity); dislocations; flux pinning; high-temperature superconductors; nanostructured materials; stacking faults; strontium compounds; superconducting epitaxial layers; transmission electron microscopy; Bi₂Sr₂CaCu₂O₈; MOCVD; antiphase boundaries; critical current density; epitaxial thin films; magnetic field dependence; misfit dislocations; nanostructural defects; pancake vortices; stacking faults; temperature 10 K; thermally activated motion; transmission electron microscopy; twin boundaries; Critical current density (superconductivity); Epitaxial growth; Magnetic fields; Superconducting magnets; Temperature dependence; Yttrium barium copper oxide; Bi2212; Superconducting thin films; critical current density; flux pinning; nanostructures; superconducting thin films;

fLanguage :

English

Journal_Title :

Applied Superconductivity, IEEE Transactions on

Publisher :

ieee

ISSN :

1051-8223

Type :

jour

DOI :

10.1109/TASC.2014.2369746

Filename :

6954494

Link To Document :

https://search.ricest.ac.ir/dl/search/defaultta.aspx?DTC=49&DC=38384