Magnetization and Static Magnetic Susceptibility of Fine-Crystalline High-Temperature YBa2Cu3O y Superconductors Synthesized by the Sol–Gel Method

A comparative study of the magnetization and static magnetic susceptibility of high-temperature superconductors (HTSC) YBa2Cu3Oy synthesized by two variants of the sol–gel method with different average sizes of crystallites 〈 D〉 ranging 0.4–2 μm has been performed in constant magnetic fields (Н ≤ 6...

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Bibliographic Details
Published in:Russian journal of physical chemistry. B 2018-09, Vol.12 (5), p.908-915
Main Authors: Mamsurova, L G, Trusevich, N G, Pigalskiy, K S, Vishnev, A A, S. Kh. Gadzhimagomedov, Zh. Kh. Murlieva, Palchaev, D K, Bugaev, A S
Format: Article
Language:English
Subjects:
Atomic properties
Coherence length
Comparative studies
Crystal structure
Crystallites
High temperature superconductors
Magnetic field penetration depth
Magnetic fields
Magnetic permeability
Magnetic properties
Magnetism
Magnetization
Oxygen atoms
Penetration depth
Physical properties
Sol-gel processes
Superconductivity
Synthesis
Temperature
Transition temperature
YBCO superconductors
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Summary:A comparative study of the magnetization and static magnetic susceptibility of high-temperature superconductors (HTSC) YBa2Cu3Oy synthesized by two variants of the sol–gel method with different average sizes of crystallites 〈 D〉 ranging 0.4–2 μm has been performed in constant magnetic fields (Н ≤ 6 kOe). It has been shown that the different annealing temperatures and times, at which their crystal structure is formed, change both the average sizes of crystallites 〈D〉 and the sizes of the structural homogeneity regions 〈l〉 and, at the same time, the magnetic field penetration depth (λ) and the coherence length (ξ). As a result, such parameters as 〈D〉 ~ λ and 〈l〉 ~ ξ become comparable, leading to a change in the physical characteristics of HTSCs. It has also been shown that the superconducting transition temperature Tc determined from the measurements of magnetic characteristics in constant magnetic fields remains within values optimal for superconductivity (Tc ≈ 92 K) in the case of an optimal number (y) of oxygen atoms, which determine the levels of charge doping for a given compound.
ISSN:1990-7931
1990-7923
DOI:10.1134/S1990793118050081