We study the hydrostatic pressure dependence of the Y123 lattice by synchrotron angle-dispersive powder diffraction up to 12.7 GPa in order to detect any lattice instabilities or phase separation observed by Raman measurements. In the pressure range (3.7 GPa < p < 10 GPa) mainly the c-axis (and to a smaller extend the a-, b-axis) undergoes a clear deviation from the expected equation of state. Upon the pressure release the data follow the anticipated dependence showing a strong hysteresis. At the pressure of ∼3.7 GPa new peaks appear in the diffraction patterns, which can be attributed to another apparently coherent phase that exhibits enhanced disorder and texture effects. The intensity of the new peaks decreases with increasing pressure and upon pressure release they disappear for p < 3.9 GPa. The in-plane Cu-O pl bonds, the Cu2-Cu1 distance and the fractional coordinate of Ba atom along the c-axis of the Y123 phase show modifications at characteristic pressures in complete agreement with the Raman measurements under pressure, strongly indicating a pressure-induced lattice instability and phase separation.
High resolution synchrotron x-ray powder diffraction combined with micro-Raman spectroscopy are
used to investigate the effect of Pr substitution for Y in optimally doped or overdoped polycrystalline
YBa2Cu3Oy
(Y123) compounds. The spectral analysis of the Raman-active
B1g-symmetry mode indicates a phase separation into coexisting nanoscopic
environments consisting of pure Y123 and Pr123 and a mixed (Y–Pr)123
phase of almost the nominal amount of Pr. The Y123 phase disappears at
x≈0.6
where superconductivity is suppressed, while the formation of the pure Pr123
phase is correlated with the increase of local lattice distortions at the Cu and Ba
sites, the presence of crystal defects and the increase of microstrains, as obtained
by analyzing the anisotropic XRD peak broadening. The comparison of the Ba
Ag-symmetry phonon
shift for the Y1−xPrxBa2Cu3Oy
and YBa2−zPrzCu3Oy
compounds as well as lattice dynamic calculations proves that, when Pr substitutes for Y,
it also occupies an amount of Ba sites. The data from Pr, La or Ca substitution for Y
indicate that loss of superconductivity is correlated with the substitution of Pr, La for Ba
and Ca for Y, though the underlying effects may not be the hole filling by these
occupancies.
Combined synchrotron angle-dispersive powder diffraction and micro-Raman spectroscopy are used to investigate pressure-induced lattice instabilities that are accompanied by superconducting Tc anomalies in YBa2Cu4O8 and optimally doped YBa2Cu3O 7−δ , in comparison with the nonsuperconducting PrBa2Cu3O6.92. In the first two superconducting systems there is a clear anomaly and hysteresis in the evolution of the lattice parameters and increasing lattice disorder with pressure, which starts at ≈ 3.7 GPa. On the contrary, in the Pr-compound the lattice parameters follow very well the expected equation of state (EOS) up to 7 GPa. The micro-Raman data of the superconducting compounds show that the energy and width of the Ag phonons exhibit anomalies over the same pressure range where the lattice parameters deviate from the EOS and the average Cu2-O pl bond length exhibits a strong contraction that correlates with the non-linear pressure dependence of Tc. The anomalous Raman behavior is not observed for the non superconducting Pr compound, clearly indicating a connection with the charge carriers. It appears that the cuprates close to optimal doping are at the edge of lattice instability.PACS numbers: 61. 05.cp, 74.25.Kc,
IntroductionIt is well accepted that structural and electronic inhomogeneities constitute intrinsic properties of cuprate superconductors [1][2][3]. To this context the study of any lattice distortions induced by application of either internal chemical or external hydrostatic pressure [4][5][6] that modify the transition temperature (T c ) is important for understanding the role of lattice effects in the high T c superconductivity. Lattice instabilities in hydrostically compressed YBa 2 Cu 3 O y (Y123) and YBa 2 Cu 4 O 8 (Y124) cuprates where T c dependence on pressure shows saturation or non-linear behavior [7,8], manifest themselves in the Raman phonon frequencies as a deviation from an expected linear behavior at a critical pressure range 2.5-6 GPa [9,10]. Recent structural investigations, using synchrotron angle-dispersive powder diffraction and dense sampling on optimally doped Y123 superconductor, have revealed in the pressure range 3.7 GPa
The mixed phase La 0.5 R 0.5 Ba 2 Cu 3 O y ͑where R is yttrium or another rare earth͒ has been prepared using a variation of the solid-state reaction technique. X-ray diffraction and Raman measurements have been carried out to study the effect of the mixed rare-earth substitution at the site of the Y atom. The x-ray-diffraction measurements show characteristic changes in the interatomic distances, which are indicative of strains in the unit cell. A strain-relaxation mechanism is proposed, attributed to the separation of phases. In the micro-Raman spectra, an increase of the A g mode frequency of the apex oxygen with increasing average La-R ionic radius is observed, the mode frequencies corresponding to the Ba and the Cu͑2͒ atoms remain practically unaffected, while in some compounds a new mode appears at ϳ126 cm Ϫ1 . The in-phase vibrations of the plane oxygen atoms show a shift to a lower frequency compared with the RBa 2 Cu 3 O y samples, similar to the one observed in the overdoped YBa 2 Cu 3 O y (yу6.92) system. Besides, the width of this phonon is considerably larger than in the YBa 2 Cu 3 O y compounds, attributable to the existence of phases with underdoped, optimally doped, and overdoped oxygen concentration. As concerns the changes induced in the B 1g Raman active mode of the out-of-phase vibrations of the plane oxygen atoms, they are indicative of phases rich in either La, R, or an intermediate phase. Differences observed from the Pr 1Ϫx R x Ba 2 Cu 3 O y compounds prove that the phase formation mechanism is not a pure ion-size effect.
High-resolution synchrotron X-ray powder diffraction (SXRPD) was used to study the temperature dependence of the oxygen-deficient NdFeAsO0.85 superconducting compound. By employing a dense temperature sampling we have managed to reveal unnoticed structural modifications that start around ∼180 K, and disappear at the transition temperature. The data show minor changes of the structural characteristics in the Nd-O charge reservoir layer while in the superconducting Fe-As layer the FeAs4 tetrahedron shows gradual modifications below ∼180 K, which suddenly disappear at Tc strongly indicating a connection with superconductivity.
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