Magnetic shielding properties of high-temperature superconducting tubes subjected to axial fields

Denis, Samuel; Dusoulier, Laurent; Dirickx, Michel; Vanderbemden, Philippe; Cloots, Rudi; Ausloos, Marcel; Vanderheyden, Benoît

doi:10.1088/0953-2048/20/3/014

Cited by 66 publications

(114 citation statements)

References 36 publications

(27 reference statements)

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“…=15,21,25,31͒ has only little effects on the results, as expected from scaling arguments. 39,68 Therefore, even though a finite n value is assumed, the sweep rate is not considered a relevant parameter affecting the results in the E-J-B conditions involved in the present study.…”

Section: A Magnetization Collapse For One Sweep Of the Transverse Fieldmentioning

confidence: 99%

Behavior of bulk high-temperature superconductors of finite thickness subjected to crossed magnetic fields: Experiment and model

et al. 2007

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Crossed-magnetic-field effects on bulk high-temperature superconductors have been studied both experimentally and numerically. The sample geometry investigated involves finite-size effects along both ͑crossed-͒ magnetic-field directions. The experiments were carried out on bulk melt-processed Y-Ba-Cu-O single domains that had been premagnetized with the applied field parallel to their shortest direction ͑i.e., the c axis͒ and then subjected to several cycles of the application of a transverse magnetic field parallel to the sample ab plane. The magnetic properties were measured using orthogonal pickup coils, a Hall probe placed against the sample surface, and magneto-optical imaging. We show that all principal features of the experimental data can be reproduced qualitatively using a two-dimensional finite-element numerical model based on an E-J power law and in which the current density flows perpendicularly to the plane within which the two components of magnetic field are varied. The results of this study suggest that the suppression of the magnetic moment under the action of a transverse field can be predicted successfully by ignoring the existence of flux-free configurations or flux-cutting effects. These investigations show that the observed decay in magnetization results from the intricate modification of current distribution within the sample cross section. The current amplitude is altered significantly only if a field-dependent critical current density J c ͑B͒ is assumed. Our model is shown to be quite appropriate to describe the cross-flow effects in bulk superconductors. It is also shown that this model does not predict any saturation of the magnetic induction, even after a large number ͑ϳ100͒ of transverse field cycles. These features are shown to be consistent with the experimental data.

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Section: A Magnetization Collapse For One Sweep Of the Transverse Fieldmentioning

confidence: 99%

Behavior of bulk high-temperature superconductors of finite thickness subjected to crossed magnetic fields: Experiment and model

et al. 2007

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“…The traditional solution of this problem consists in using a piece of ferromagnetic material instead, which can divert the magnetic flux outside the region to be protected [1]. However, hard type-II superconductors, which are strongly diamagnetic, can shield a magnetic field more efficiently than ferromagnetic materials do [2][3][4][5][6], In a recent work [7], we have studied numerically and experimentally the shielding properties of open type-II superconducting tubes that were subjected to a source field applied parallel to the tube axis (parallel geometry). Three factors were considered to evaluate the quality of the shields: (i) the maximum induction that can be strongly attenuated, called B lim , (ii) the spatial variation of the field attenuation, and (iii), the frequency dependence of the field attenuation.…”

Section: Introductionmentioning

confidence: 99%

“…The results of [7] can be used to design better magnetic shields. For instance, putting a cap at both ends of the tube reduces the penetration from the extremities and thus raises the level of attenuation inside the tube.…”

Section: Introductionmentioning

confidence: 99%

Field penetration into hard type-II superconducting tubes: effects of a cap, a non-superconducting joint, and non-uniform superconducting properties

Denis

Dirickx

Vanderbemden

et al. 2007

Supercond. Sci. Technol.

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Using the numerical method of Brandt (1998 Phys. Rev. B 58 6506), we study the penetration of a uniform magnetic field that is gradually applied parallel to the axis of finite type-II superconducting tubular samples with strong pinning. This study is carried out in view of designing low-frequency magnetic shields by exploiting the diamagnetic properties of type-II superconductors. First, we compare the field penetration into open and closed tubes. For long tubes (length larger than three times the outer diameter), we show that a cap weakly affects the maximum magnetic induction that can be shielded, but greatly increases the region over which the field is nearly uniform. When the length of the tube is shorter, both the maximum shieldable magnetic induction and the uniformity of the field attenuation are enhanced by closing the tube. We also show that making a hole in the cap, which is often necessary for applications, does not greatly affect the shielding properties provided the diameter of the hole is small compared to that of the tube (hole diameter smaller than a quarter of the outer tube diameter). In view of designing large size magnetic shields, superconducting tubes of finite size need to be joined together. We therefore examine in a second part how the presence of a non-superconducting joint between the tubes affects the shielding efficiency. It is shown that the effect of a joint depends upon its position along the tube axis and strongly increases with its size. Third, we study how non-uniform superconducting properties affect the shielding capabilities.

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“…Finally, the simple hard wall model described by Bergström [82] was used to approximate the steric stabilization in the YBCO suspension stabilised in I 2 solution, by means: (9) δ represents the thickness of the adsorbed layer, Φ the volume fraction of the adsorbent in the adsorbed layer, is the solvent-adsorbent interaction parameter and V is the molecular volume solvent. This equation is valid in the interpenetrational domain ( 2 ) 2 ( d D ) [82].…”

Section: Dispersing Mechanism Of Ybco Particles In Acetone-i 2 Solutionmentioning

confidence: 99%

“…In this sense EPD should be considered as a potential applicable technique, offering a real possibility of industrial scalability and reliability. In fact, EPD has been successfully considered for applications such as magnetic shielding in low frequencies [6][7][8][9][10][11][12]. However, much effort is still necessary to understand and control the complex colloidal behaviour and the surface reactions occurring when YBCO powders are dispersed in a liquid.…”

Section: Introductionmentioning

confidence: 99%

YBa2Cu3O7−x dispersion in iodine acetone for electrophoretic deposition: Surface charging mechanism in a halogenated organic media

Dusoulier

Cloots

Vertruyen

et al. 2011

Journal of the European Ceramic Society

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Electrophoretic Deposition (EPD) performance strongly depends on the particles surface chemistry and the ability to manipulate surface-liquid interfaces. In this study an extensive investigation of YBCO suspension in dry acetone, acetone-water mixtures and acetone-iodine is reported. Chemical instability of YBCO particles determines their colloidal behaviour. Charging mechanism of particles has therefore had to be deeply investigated for complete dispersion understanding. In order to determine the conditions of the YBCO suspension stability, measurements of pH, conductivity, zeta-potential, settling tests, modelling of the particle networks and electrophoretic deposition were done. The influence of the water and iodine concentration, and their role as stabilizers was evaluated. Based on experimental results, pair particle potentials were calculated and then different charging mechanisms of YBCO surfaces in acetone were proposed.

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Magnetic shielding properties of high-temperature superconducting tubes subjected to axial fields

Cited by 66 publications

References 36 publications

Behavior of bulk high-temperature superconductors of finite thickness subjected to crossed magnetic fields: Experiment and model

Behavior of bulk high-temperature superconductors of finite thickness subjected to crossed magnetic fields: Experiment and model

Field penetration into hard type-II superconducting tubes: effects of a cap, a non-superconducting joint, and non-uniform superconducting properties

YBa2Cu3O7−x dispersion in iodine acetone for electrophoretic deposition: Surface charging mechanism in a halogenated organic media

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