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Lu, D. H.; Feng, D. L.; Armitage, N. P.; Shen, Kyle; Damascelli, A.; Kim, C.; Ronning, F.; Shen, Z.‐X.; Bonn, D. A.; Liang, Ruixing; Hardy, W. N.; Rykov, Alexandre I.; Tajima, S.

doi:10.1103/physrevlett.86.4370

Cited by 163 publications

(181 citation statements)

References 19 publications

(27 reference statements)

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“…However, along the crystallographic b-direction this is much more pronounced than along a, and the analysis of both data sets in terms of s + d wave gaps using (5) reveals that along the a direction the s-wave order parameter contributes 14%, whereas along the b direction the s-wave contribution is 42%. This assignment is supported by photoemission experiments on YBa 2 Cu 3 O 6.993 , where a 50% difference in the magnitude of the superconducting gaps was reported [29]. In addition, these data provide evidence that this anisotropy is not a consequence of the chain related electronic structure, but intrinsic to the CuO 2 planes.…”

Section: Is the Maximum Value Of The Gap And (T ϕ) = 0˜ (T /T C )Gsupporting

confidence: 71%

s-Wave Symmetry Along the c-Axis and s+d In-plane Superconductivity in Bulk YBa2Cu4O8

Khasanov

Shengelaya

Karpiński

et al. 2007

J Supercond Nov Magn

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To clarify the order parameter symmetry of cuprates, the magnetic penetration depth λ was measured along the crystallographic directions a, b, and c in single crystals of YBa 2 Cu 4 O 8 via muon spin rotation. This method is direct, bulk sensitive, and unambiguous. The temperature dependences of λ −2 a and λ −2 b exhibit an inflection point at low temperatures as is typical for two-gap superconductivity (TGS) with s + d-wave character in the planes. Perpendicular to the planes a pure s-wave gap is observed thereby highlighting the important role of c-axis effects. We conclude that these are generic and universal features in the bulk of cuprates. Recently, new muon spin rotation (μSR) investigations of single crystal La 1.83 Sr 0.17 CuO 4 detected an inflection point in the temperature dependence of the inverse-squared in-plane magnetic penetration depth λ −2 ab , which is a direct consequence of two superconducting gaps with largely different zero temperature gap values [14]. Since it is unclear whether these observations are a material specific property or generic and intrinsic to HTS, the previous μSR studies were extended to single crystal YBa 2 Cu 4 O 8 and were performed by applying a magnetic field along the crystallographic directions a, b, and c. Thereby we obtain the three principle components of the second moments of the local magnetic field distribution P (B) in the mixed state, which are related to the superfluid density, and reflect directly the corresponding penetration depths λ a , λ b , and λ c . While λ −2 a and λ −2 b vary almost linearly with temperature for 20 < T < 50 K, as is expected for a d-wave order parameter, the c-axis response (λ −2 c ) saturates below 30 K, as expected for a s-wave order parameter. In addition, λ −2 a and PACS

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Section: Is the Maximum Value Of The Gap And (T ϕ) = 0˜ (T /T C )Gsupporting

confidence: 71%

s-Wave Symmetry Along the c-Axis and s+d In-plane Superconductivity in Bulk YBa2Cu4O8

Khasanov

Shengelaya

Karpiński

et al. 2007

J Supercond Nov Magn

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show abstract

“…It is also noteworthy that y directed stripes not only lead to substantial low energy spectral weight in the anti-nodal region near (0, π), as naively expected, but also in the reciprocal region, near (π, 0), as well. (This observation is important in systems with macroscopic stripe orientational order, including, potentially, YBCO [12].) We also note that for the ordered array, there are oscillations in the spectral weight as a function of k x .…”

Section: Figmentioning

confidence: 93%

Distribution of spectral weight in a system with disordered stripes

et al. 2002

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The "band-structure" of a disordered stripe array is computed and compared, at a qualitative level, to angle resolved photoemission experiments on the cuprate high temperature superconductors. The low-energy states are found to be strongly localized transverse to the stripe direction, so the electron dynamics is strictly one-dimensional (along the stripe). Despite this, aspects of the two dimensional band-structure Fermi surface are still vividly apparent.

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“…Such a large anisotropy is not consistent with tunneling measurements of the gap; it is possible that the anisotropy is reduced by strong interstripe coupling. On the other hand, a large gap anisotropy has been found in YBCO 70 , where the stripes are aligned along the chain direction 3 . In Ref.…”

Section: B Modifications Due To Magnetic Ordermentioning

confidence: 99%

Phase separation models for cuprate stripe arrays

Markiewicz

Kusko

2002

Phys. Rev. B

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An electronic phase separation model provides a natural explanation for a large variety of experimental results in the cuprates, including evidence for both stripes and larger domains, and a termination of the phase separation in the slightly overdoped regime, when the average hole density equals that on the charged stripes. Several models are presented for charged stripes, showing how density waves, superconductivity, and strong correlations compete with quantum size effects (QSEs) in narrow stripes. The energy bands associated with the charged stripes develop in the middle of the Mott gap, and the splitting of these bands can be understood by considering the QSE on a single ladder.

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Superconducting Gap and Strong In-Plane Anisotropy in UntwinnedYBa2Cu3O7−
D. H. Lu
¹
,
D. L. Feng
²
,
N. P. Armitage
³

et al.

Cited by 163 publications

References 19 publications

s-Wave Symmetry Along the c-Axis and s+d In-plane Superconductivity in Bulk YBa2Cu4O8

s-Wave Symmetry Along the c-Axis and s+d In-plane Superconductivity in Bulk YBa2Cu4O8

Distribution of spectral weight in a system with disordered stripes

Phase separation models for cuprate stripe arrays

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Superconducting Gap and Strong In-Plane Anisotropy in UntwinnedYBa2Cu3O7−D. H. Lu1, D. L. Feng2, N. P. Armitage3 et al.

Cited by 163 publications

References 19 publications

s-Wave Symmetry Along the c-Axis and s+d In-plane Superconductivity in Bulk YBa2Cu4O8

s-Wave Symmetry Along the c-Axis and s+d In-plane Superconductivity in Bulk YBa2Cu4O8

Distribution of spectral weight in a system with disordered stripes

Phase separation models for cuprate stripe arrays

Contact Info

Product

Resources

About

Superconducting Gap and Strong In-Plane Anisotropy in UntwinnedYBa2Cu3O7−
D. H. Lu
¹
,
D. L. Feng
²
,
N. P. Armitage
³

et al.