Oxide electronics

SPIN-CHARGE-LATTICE COUPLING IN REDUCED DIMENSIONS IN THE CMR OXIDE La_2-2xSr_1+2xMn₂O₇, x=0.3-0.5

ACTA CRYSTALLOGRAPHICA A-FOUNDATION AND ADVANCES 55 (1999) 179-179

Authors:

Dimitri N Argyriou, John F Mitchell, Jason Gardner, Paolo G Radaelli, David E Cox, Heloisa N Bordallo, James D Jorgensen

STUDY OF CRYSTALLOGRAPHIC STRUCTURE OF THE COLOSSAL MAGNETO-RESISTANCE COMPOUND La_0.75Ca_0.25MnO₃

ACTA CRYSTALLOGRAPHICA A-FOUNDATION AND ADVANCES 55 (1999) 496-496

Authors:

G Iannone, C Meneghini, S-W Cheong, DD Sarma, PG Radaelli

Structure of HgBa₂CuO_4+δ (0.06<δ<0.19) at ambient and high pressure

PHYSICAL REVIEW B 59:10 (1999) 7209-7215

Authors:

AM Balagurov, DV Sheptyakov, VL Aksenov, EV Antipov, SN Putilin, PG Radaelli, M Marezio

"Wigner crystal" and "stripe" models for the magnetic and crystallographic superstructures of La0.333Ca0 .667MnO3

ArXiv cond-mat/9812366 (1998)

Authors:

PG Radaelli, DE Cox, L Capogna, S-W Cheong, M Marezio

Abstract:

The crystallographic (charge-ordered) and magnetic superstructures of La0.333Ca0.667MnO3 were studied by high-resolution synchrotron x-ray and neutron powder diffraction. In the antiferromagnetic structure, which was refined using a non-collinear model, the a lattice parameter is tripled and the c lattice parameter is doubled with respect to the average crystallographic unit cell (Pnma setting). The crystallographic structure below the charge-ordering temperature (TCO ~ 260 K) is characterized by ordering of the dz2 orbitals of the Jahn-Teller-distorted Mn3+O6 octahedra in the orthorhombic ac plane, and the appearance of superlattice peaks in the x-ray patterns corresponding to a tripling of the a axis lattice parameter. The intensities of the superlattice peaks can be accounted for satisfactorily in terms of ordering of the Mn3+ cations in sites as far apart as possible in the ac plane ("Wigner crystal" model) and transverse displacements of the Mn4+O6 octahedra in the c direction. These results are not consistent with a recently proposed model based on transmission electron microscopy (TEM) data in which the Mn3+O6 octahedra are arranged in a stripe pattern ("stripe" model). In particular, the large longitudinal stripe modulation revealed by TEM is not observed, suggesting that the TEM data may not be representative of the bulk sample. Within the framework of the "Wigner crystal" model, the magnetic structure at 1.5 K and the charge-ordered superstructure at 160 K and 1.5 K were refined from the neutron data.

Acoustic phase velocity measurements with nanometer resolution by scanning acoustic forcemicroscopy

Applied Physics A: Materials Science and Processing 66:SUPPL. 1 (1998)

Authors:

E Chilla, T Hesjedal, HJ Fröhlich

Abstract:

With the increasing interest in nanostructures and thin films, the need for a quantitative measuring method for elastic constants on the nanometer scale has become more evident. The fundamental physical quantity characterizing the elastic constants is the acoustic phase velocity. Due to the strong localization of surface acoustic waves (SAWs) in the near-surface region, SAWs are particularly favored for such investigations. The velocity measurement is commonly performed by time delay and acoustic far-field methods. Therefore the lateral resolution of the velocity measurement is restricted by the wavelength involved to some tens of microns. Recently, we introduced the scanning acoustic force microscope (SAFM) for the measurement of SAW amplitude distributions with nanometer lateral resolution. The key to detecting high-frequency surface oscillations by the slowly responding force microscope cantilever is the nonlinear force curve. This nonlinearity can be exploited in a heterodynetype setup for high-frequency wave mixing of a probe and a reference wave, revealing the phase of the probe wave. The difference frequency can be chosen to be as low as 1 kHz. We present measurements of the phase velocity over a lateral distance of 19:9 nm. The phase velocity dispersion due to Au layers on a quartz substrate was measured over distances as small as 200 nm and compared with calculations. © 1998 Springer-Verlag.