The crystal structure of the anion-deficient perovskite Ca2.5Sr0.5GaMn2O8 has
been studied at 290 and 5 K by neutron diffraction (290 K; space group
Pcm21,
a = 5.4294(1), b = 11.3722(3), c = 5.2983(1)Å).
The vacant oxide sites order to create a structure in which perovskite
bilayers consisting of MnO6 octahedra are isolated from each other
along [010] by a single layer of GaO4 tetrahedra. At 5 K the material
is antiferromagnetic with an ordered magnetic moment of 3.09(1) μB
per Mn cation. Magnetic susceptibility measurements suggest that short-range
magnetic ordering within the bilayers occurs above 200 K, and muon spin
relaxation data show that the transition to long-range magnetic order occurs
between 150 and 125 K. The resistivity of Ca2.5Sr0.5GaMn2O8 decreases by an
order of magnitude at 125 K, and ∼50% magnetoresistance is seen in a field of 80
kOe at 110 K.
We present a novel approach to the detection of special nuclear material using cosmic rays. Muon Scattering Tomography (MST) is a method for using cosmic muons to scan cargo containers and vehicles for special nuclear material. Cosmic muons are abundant, highly penetrating, not harmful for organic tissue, cannot be screened against, and can easily be detected, which makes them highly suited to the use of cargo scanning.
Muons undergo multiple Coulomb scattering when passing through material, and the amount of scattering is roughly proportional to the square of the atomic number Z of the material. By reconstructing incoming and outgoing tracks, we can obtain variables to identify high-Z material. In a real life application, this has to happen on a timescale of 1 min and thus with small numbers of muons.
We have built a detector system using resistive plate chambers (RPCs): 12 layers of RPCs allow for the readout of 6 x and 6 y positions, by which we can reconstruct incoming and outgoing tracks. In this work we detail the performance of an algorithm by which we separate high-Z targets from low-Z background, both for real data from our prototype setup and for MC simulation of a cargo container-sized setup.
(c) British Crown Owned Copyright 2013/AWE
We present the results of muon-spin-relaxation experiments for two materials which show geometric frustration. ZnCr 2 O 4 has a spinel structure with S = 3 2 spins on a lattice of corner-sharing tetrahedra. Our experiments show that a local magnetic field which is quasi-static on the muon timescale develops below T c = 12.5 K, a transition which has been associated with a three-dimensional analogue of the spin-Peierls transition. In contrast, Gd 3 Ga 5 O 12 has a garnet structure with S = 7 2 spins arranged on interpenetrating triangular sublattices. In this material the muon data exhibit a temperature-dependent spin-relaxation rate indicative of slow spin fluctuations. We discuss these differing behaviours and relate them to the underlying physics in the two materials.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.