Isotope Effect in the Superfluid Density of High-Temperature Superconducting Cuprates: Stripes, Pseudogap, and Impurities

Tallon, J. L.; Islam, R. S.; Storey, J. G.; Williams, G. V. M.; Cooper, J. R.

doi:10.1103/physrevlett.94.237002

Cited by 49 publications

(47 citation statements)

References 29 publications

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“…20,21 Nevertheless, OIE on the penetration depth is nearly constant from the optimally doped sample to the substituted samples with a large amount of Pr, 14 which is inconsistent with the theoretical prediction. 20 We would like to emphasize here that since the pairbreaking effect in optimally doped cuprates is negligibly small and the carrier concentrations of the two oxygenisotope samples have been consistently proved to be the same within Ϯ0.0002 per Cu, 2,23 the observed large oxygenisotope effect on the penetration depth must be caused by the large oxygen-isotope effect on the supercarrier mass. The origin of this unconventional isotope effect could arise from strong EPI that causes the breakdown of the Migdal approximation.…”

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confidence: 45%

“…20,21 Two different groups 20,21 have consistently shown that the isotope effects on T c and the penetration depth are almost proportional to each other provided that the strong pair-breaking effect exists. These theoretical models may be able to explain the observed large oxygen-isotope effects on both T c and the penetration depth in underdoped cuprates if the scattering rate were large enough.…”

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confidence: 99%

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Comment on “Isotope effect in high-Tcsuperconductors”

Alexandrov

Zhao

2009

Phys. Rev. B

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confidence: 45%

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confidence: 99%

Comment on “Isotope effect in high-Tcsuperconductors”

Alexandrov

Zhao

2009

Phys. Rev. B

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“…5,6 The cuprate high-temperature superconductors (HTS) are characterized by a vanishingly small but positive isotope effect exponent in optimally doped compounds which increases in a monotonic way upon decreasing doping. [7][8][9][10][11][12][13][14] For the optimally doped cuprate HTS the smallest value of the oxygen-isotope exponent α O ≃ 0.02 was obtained for YBa 2 Cu 3 O 7−δ and Bi 2 Sr 2 Ca 2 Cu 3 O 10+δ , while it reaches α O ≃ 0.25 for Bi 2 Sr 1.6 La 0.4 CuO 6+δ . [7][8][9]13,14 In addition, it was demonstrated that in underdoped materials α O exceeds substantially the BCS limit α BCS ≡ 0.5.…”

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Intrinsic and structural isotope effects in iron-based superconductors

et al. 2010

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The currently available results of the isotope effect on the superconducting transition temperature Tc in Fe-based high-temperature superconductors (HTSs) are highly controversial. The values of the Fe isotope effect exponent Fe for various families of Fe-based HTS were found to be as well positive, as negative, or even be exceedingly larger than the BCS value BCS 0.5. Here we emphasize that the Fe isotope substitution causes small structural modifications which, in turn, affect Tc. Upon correcting the isotope effect exponent for these structural effects, an almost unique value of 0.35-0.4 is observed for at least three different families of Fe-based HTS.

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“…Also the low value of α O n = 0.146 in [25] is in sharp contrast to the observed very large OIE on the lowtemperature magnetic-field penetration depth, λ ab ∝ (m * * ab /n) 1/2 , in both La 1.94 Sr 0.06 CuO 4 (see [9]) and Y 0.55 Pr 0.45 Ba 2 Cu 3 O 7−y (see [26]), which would lead to α O n 2 if one assumed that the supercarrier mass is independent of the oxygen mass. Another model based on the pair-breaking effects due to impurities, disorder and/or pseudogap can also explain the observed OIEs on the penetration depth and critical temperature in deeply underdoped samples [27]. But this model cannot consistently explain the negligibly small α O but large OIE on the penetration depth in optimally doped samples [10].…”

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Isotope effects in high-T_ccuprate superconductors as support for the bipolaron theory of superconductivity

Alexandrov

Zhao

2012

New J. Phys.

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We provide a unified parameter-free explanation of the observed oxygen-isotope effects on the critical temperature, the magnetic-field penetration depth and on the normal-state pseudogap for underdoped cuprate superconductors within the framework of the multi-(bi)polaron theory with strong Coulomb and Fröhlich interactions. We also quantitatively explain the measured critical temperature and the magnitude of the magnetic-field penetration depth. This paper thus represents an important support for the bipolaron theory of high-temperature superconductivity, compatible with many other independent observations. On the long journey towards a microscopic understanding of superconductivity, the observation of an isotope effect on the critical temperature, T c , in 1950 [1,2] provided an important clue to the microscopic mechanism of superconductivity. The presence of an isotope effect thus implies that superconductivity is not of purely electronic origin. In the same year, Fröhlich [3] pointed out that the electron-phonon interaction gave rise to an attractive interaction between electrons, which might be responsible for superconductivity. Fröhlich's theory played a decisive role in establishing the correct mechanism. Finally, in 1957, Bardeen, Cooper and Schrieffer (BCS) [4] developed the BCS theory that was the first successful microscopic theory of superconductivity. The BCS theory implies an isotope-mass dependence of T c , with an isotope-effect exponent α = −d ln T c /d ln M = 1/2, in excellent agreement with the reported isotope exponents in simple metallic superconductors such as Hg, Sn and Pb.The doping-dependent oxygen-isotope effect (OIE) on the critical temperature T c , α O = −d ln T c /d ln M O (where M O is the oxygen-isotope mass) [5] and the substantial OIE on the in-plane supercarrier mass m * * ab , α O m * = dm * * ab /d ln M O [6-11], provide direct evidence for a significant electron-phonon interaction (EPI) also in high-temperature cuprate superconductors. High-resolution angle-resolved photoemission spectroscopy (ARPES) [12] provides further evidence for strong EPI with c-axis-polarized optical phonons [13]. These results, along with optical [14], neutron scattering [15,16] and tunneling data [17][18][19], unambiguously show that lattice vibrations play a significant but unconventional role in high-temperature superconductivity. The interpretation of the optical spectra of high-T c materials as the polaron absorption [20,21] strengthens the view [22] that the Fröhlich EPI is important in those structures. Operating together with a shorter-range deformation potential and molecular-type (e.g. Jahn-Teller [23]) EPIs, the Fröhlich EPI can readily overcome the Coulomb repulsion at a short distance of about the lattice constant for electrons to form real-space inter-site bipolarons [24].Despite all these remarkable and well-performed experiments that lead to the consistent conclusion about the important role of EPI in high-temperature superconductors, there is no consensus on the microscopic origin of ...

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Isotope Effect in the Superfluid Density of High-Temperature Superconducting Cuprates: Stripes, Pseudogap, and Impurities

Cited by 49 publications

References 29 publications

Comment on “Isotope effect in high-Tcsuperconductors”

Comment on “Isotope effect in high-Tcsuperconductors”

Intrinsic and structural isotope effects in iron-based superconductors

Isotope effects in high-T_ccuprate superconductors as support for the bipolaron theory of superconductivity

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Isotope Effect in the Superfluid Density of High-Temperature Superconducting Cuprates: Stripes, Pseudogap, and Impurities

Cited by 49 publications

References 29 publications

Comment on “Isotope effect in high-Tcsuperconductors”

Comment on “Isotope effect in high-Tcsuperconductors”

Intrinsic and structural isotope effects in iron-based superconductors

Isotope effects in high-Tccuprate superconductors as support for the bipolaron theory of superconductivity

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Product

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Isotope effects in high-T_ccuprate superconductors as support for the bipolaron theory of superconductivity