Local lattice anomalies in optimally doped T-(La,Sr)2CuO4 single crystal like thin films (T c = 43.4 K) grown by molecular-beam epitaxy have been studied by the in-plane polarized Cu K-edge extended X-ray absorption fine structure (EXAFS). The results indicate temperature-dependent local atomic displacements which are anomalous at the T c and below a higher temperature T s as demonstrated by a change in the mean square relative displacement of the Cu–O bond 2Cu−O, i.e., a sharp drop at the T c and a gradual deviation from a noncorrelated Debye-like behavior below T s where the spatial inhomogeneity appears. We find that the magnitude of the Cu–O displacement changes at the T c, 2Cu−O is enhanced by compressive strain while the tendency of charge segregation is suppressed. The results suggest that the uniaxial pressure effects stabilize the system by decreasing the onset temperature and magnitude of spatial heterogeneity.
Lattice Anomalies in (La,Sr)2CuO4 Under Epitaxial Strain Probed by Polarized X-Ray Absorption Spectroscopy / H., Oyanagi; Saini, Naurang Lal; A., Tsukada; AND M., Naito. - In: JOURNAL OF SUPERCONDUCTIVITY. - ISSN 0896-1107. - 18:(2005), pp. 731-735. [10.1007/s10948-005-0070-6]
Lattice Anomalies in (La,Sr)2CuO4 Under Epitaxial Strain Probed by Polarized X-Ray Absorption Spectroscopy
SAINI, Naurang Lal;
2005
Abstract
Local lattice anomalies in optimally doped T-(La,Sr)2CuO4 single crystal like thin films (T c = 43.4 K) grown by molecular-beam epitaxy have been studied by the in-plane polarized Cu K-edge extended X-ray absorption fine structure (EXAFS). The results indicate temperature-dependent local atomic displacements which are anomalous at the T c and below a higher temperature T s as demonstrated by a change in the mean square relative displacement of the Cu–O bond 2Cu−O, i.e., a sharp drop at the T c and a gradual deviation from a noncorrelated Debye-like behavior below T s where the spatial inhomogeneity appears. We find that the magnitude of the Cu–O displacement changes at the T c, 2Cu−O is enhanced by compressive strain while the tendency of charge segregation is suppressed. The results suggest that the uniaxial pressure effects stabilize the system by decreasing the onset temperature and magnitude of spatial heterogeneity.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
