High-temperature superconductivity

Dow, John D.; Harshman, Dale R.

doi:10.1590/s0103-97332003000400008

Cited by 8 publications

(2 citation statements)

References 22 publications

(33 reference statements)

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“…Since their discovery, the list of high-T C superconductor families has grown to include (i) the (well-known) layered cuprate perovskites (e.g. YBa 2 Cu 3 O 7-δ ), (ii) ruthenocuprates such as GdSr 2 Cu 2 RuO 8 [114], and certain Cu-doped layered ruthenates [82,115] ). Since the latter five families (iii)-(vii) of compounds in addition to the ruthenates do not contain cuprate planes, it is manifestly clear that CuO 2 planes are not specifically required for high-T C superconductivity.…”

Section: Discussionmentioning

confidence: 99%

Theory of high-T_Csuperconductivity: transition temperature

Harshman

Fiory

Dow

2011

J. Phys.: Condens. Matter

157

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The superconducting transition temperatures of high-T C compounds based on copper, iron, ruthenium and certain organic molecules are discovered to be dependent on bond lengths, ionic valences, and Coulomb coupling between electronic bands in adjacent, spatially separated layers. 1 Optimal transition temperature, denoted as T C0 , is given by the universal expression k B T C0 = e 2  / ℓζ; ℓ is the spacing between interacting charges within the layers, ζ is the distance between interacting layers and  is a universal constant, equal to about twice the reduced electron Compton wavelength (suggesting that Compton scattering plays a role in pairing). Non-optimum compounds in which sample degradation is evident typically exhibit T C < T C0 . For the 31+ optimum compounds tested, the theoretical and experimental T C0 agree statistically to within  1.4 K. The elemental high T C building block comprises two adjacent and spatially separated charge layers; the factor e 2 / ζ arises from Coulomb forces between them. The theoretical charge structure representing a room-temperature superconductor is also presented.

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Section: Discussionmentioning

confidence: 99%

Theory of high-T_Csuperconductivity: transition temperature

Harshman

Fiory

Dow

2011

J. Phys.: Condens. Matter

157

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“…[3] Specific heat and magnetic susceptibility measurements reveal two phase transitions at ∼ 30 K and ∼ 26 K respectively, [1] while the physical state of Sr 2 YRuO 6 between these two transition temperatures continues to be elucidated. Additional interest in this material is originated from the occurrence of superconductivity when Ru is partially (up to 15%) replaced by Cu in both powders [3][4][5][6][7] and single crystals, [8][9][10] with superconducting volume fractions still under 10%. A broad knowledge of the magnetic state of Sr 2 YRuO 6 is fundamental to understand how the superconducting and ferromagnetic order parameters can adjust themselves in the crystal lattice.…”

Section: Introductionmentioning

confidence: 99%

Magnetic properties of the double perovskite compound Sr₂YRuO₆

Mekkaoui¹,

Idrissi²,

Mtougui³

et al. 2019

Chinese Phys. B

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We study the magnetic properties of the double perovskite ruthenate compound Sr2YRuO6 using Monte Carlo simulations (MCS). We elaborate the ground state phase diagrams for all possible and stable configurations. The magnetizations and the susceptibilities as a function of temperature for the studied system are also reported. The effects of the exchange coupling interactions and the crystal field are examined and discussed. On the other hand, since the compound Sr2YRuO6 exhibits an antiferromagnetic behavior, we find its Néel temperature, T N ≈ 31 K , which is in good agreement with the experimental results in the literature. To complete this study, the hysteresis loops and the coercive field as a function of the external magnetic field are also obtained for fixed values of the physical parameters.

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