Effect of the Composition and the Crystal Structure on the Electrophysical Properties of the Ni1–xWx System at Low Temperatures

Derevyanko, V. V.; Sungurov, M. S.; Sukhareva, T. V.; Finkel, V. A.; Shakhov, Yu. N.

doi:10.1134/s1063783418100062

Cited by 8 publications

(6 citation statements)

References 12 publications

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“…To date, a model has been proposed that explains the totality of the magnetotransport properties of [21][22][23][24][25][26][27][28][29], which at first glance are difficult to explain. It is possible to note a series of recent works in which features of the behavior of the electrical resistance of granular Y−Ba−Cu−O in external fields were discovered, indicating the course of the Berezinsky-Kosterlitz-Taules topological phase transition in the intergranular medium [30][31][32][33][34]. For some low-temperature superconductors, effects related to the Josephson coupling between superconducting granules [35][36][37], or superconducting areas, are also observed [38], and, as a consequence, with the implementation of a two-level superconducting system.…”

Section: Introductionmentioning

confidence: 93%

Influence of intragranular Meissner currents and magnetic flux trapped in granules on the effective field in the intergranular medium and the magnetoresistance hysteresis of a granular HTSC

Balaev

S.V.

Gokhfeld

2022

Physics of the Solid State

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The concept of an effective field in an intergranular medium is used to describe the hysteresis magnetoresistance of granular HTSCs. This effective field is a superposition of the external magnetic field and the field induced by the magnetic moments of the superconducting granules. The magnetic moment of the granules is contributed by the shielding currents and the trapped magnetic flux. We studied and analyzed the effect of the trapped flux on the magnetoresistance. It has been experimentally shown that the dependence of the residual resistance RRem (after applying of the external field) on the trapped flux clearly correlates with the behavior of the remanent magnetization. In addition, special attention was paid to a detailed comparison of the magnetoresistance of the granular YBa2Cu3O7-delta for two cases: (a) the magnetization of HTSC-granules is caused only by the trapped magnetic flux (in a zero external field) and (b) HTSC-granules are in the Meissner state (the external field is smaller than the first critical field of the granules). It has been found that Abrikosov vortices and intragranular Meissner currents differently affect the effective field in the intergranular medium (for the same values (of magnetization for cases (a) and (b) ). A possible reason for this difference is discussed. Keywords: granular HTSC, magnetoresistance hysteresis, magnetization hysteresis, trapped flux, screening currents.

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Section: Introductionmentioning

confidence: 93%

Influence of intragranular Meissner currents and magnetic flux trapped in granules on the effective field in the intergranular medium and the magnetoresistance hysteresis of a granular HTSC

Balaev

S.V.

Gokhfeld

2022

Physics of the Solid State

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“…Let us introduce the two-dimensional critical-current density j c (B Z ). The relation of the three-dimensional critical current density J c (Z) and j c (B Z ) is determined as follows: (1) where h is the superconducting layer thickness.…”

Section: Sample Characteristics and Irradiation Conditionsmentioning

confidence: 99%

“…An inhomogeneity of the defect distribution in a semiconductor can lead to local inhomogeneity of changing the superconducting characteristics in the material bulk. This inhomogeneity, in turn, can lead to unusual physical phenomena, for example, the appearance of phase transition in current similar to the transitions observed in granular HTSC YBa 2 Cu 3 O 7 -x [1]. In this work, we propose and justify an express magnetometric technique which allows the determination of the inhomogeneity of changes in supercon-ducting properties of a thin layer of GdBa 2 Cu 3 O 7 -x (GdBaCuO123) superconductor caused by radiation irradiation.…”

Section: Introductionmentioning

confidence: 97%

On Magnetometric Determination of the Radiation Defect Concentration in a Superconducting GdBa2Cu3O7 – x Film

Подливаев

2021

Phys. Solid State

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An express magnetometric technique which enables the determination of inhomogeneities of changing the superconducting properties of a thin semiconductor layer due to a radiation irradiation is proposed and justified. This technique is numerically simulated for a superconducting GdBa 2 Cu 3 O 7 -x layer irradiated with hydrogen and helium ions. The concentration profile of radiation defects is calculated using the SRIM program package. The distribution of the density of superconducting currents induced by an external magnetic field is calculated in terms of the critical state model. The model calculations demonstrate the efficiency of the proposed technique.

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“…К настоящему времени предложена модель, объясняющая совокупность, на первый взгляд, сложных для объяснения, магнитотранспортных свойств [21][22][23][24][25][26][27][28][29]. Можно отметить серию недавних работ, в которых были обнаружены особенности поведения электросопротивления гранулярного Y−Ba−Cu−O во внешних полях, указывающие на протекание топологического фазового перехода Березинского-Костерлица-Таулеса в межгранульной среде [30][31][32][33][34]. Для некоторых низкотемпературных сверхпроводников также наблюдаются эффекты, связанные с джозефсоновской связью между сверхпроводящими гранулами [35][36][37], или сверхпроводящими областями [38], и, как следствие, с реализацией двухуровневой сверхпроводящей системы.…”

Section: Introductionunclassified

Влияние Внутригранульных Мейсснеровских Токов И Захваченного В Гранулах Потока На Эффективное Поле В Межгранульной Среде И Гистерезис Магнитосопротивления Гранулярного ВТСП

Балаев¹,

Семенов²,

Гохфельд³

2022

Физика Твердого Тела

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The concept of an effective field in an intergranular medium is used to describe the hysteresis magnetoresistance of granular HTSCs. This effective field is a superposition of the external magnetic field and the field induced by the magnetic moments of the superconducting granules. The magnetic moment of the granules is contributed by the shielding currents and the trapped magnetic flux. We studied and analyzed the effect of the trapped flux on the magnetoresistance. It has been experimentally shown that the dependence of the residual resistance (after applying of the external field) on the trapped flux clearly correlates with the behavior of the remanent magnetization. In addition, special attention was paid to a detailed comparison of the magnetoresistance of the granular YBa2Cu3O7-delta for two cases: (a) the magnetization of HTSC granules is caused only by the trapped magnetic flux (in a zero external field) and (b) HTSC granules are in the Meissner state (the external field is smaller than the first critical field of the granules). It has been found that Abrikosov vortices and intragranular Meissner currents differently affect the effective field in the intergranular medium (for the same values of magnetization for cases (a) and (b)). A possible reason for this difference is discussed.

show abstract

Effect of the Composition and the Crystal Structure on the Electrophysical Properties of the Ni1–xWx System at Low Temperatures

Cited by 8 publications

References 12 publications

Influence of intragranular Meissner currents and magnetic flux trapped in granules on the effective field in the intergranular medium and the magnetoresistance hysteresis of a granular HTSC

Influence of intragranular Meissner currents and magnetic flux trapped in granules on the effective field in the intergranular medium and the magnetoresistance hysteresis of a granular HTSC

On Magnetometric Determination of the Radiation Defect Concentration in a Superconducting GdBa2Cu3O7 – x Film

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