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Neutron Scattering Study on UTGa5 and NpTGa5

Published online by Cambridge University Press:  26 February 2011

Naoto Metoki
Naoto Metoki*
Affiliation:
metoki.naoto@jaea.go.jp, Japan Atomic Energy Agency, Advanced Science Research Center, Tokai Naka, Ibaraki, 319-1195, Japan, 81-29-284-3872, 81-29-282-5939
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Abstract

The results of our recent neutron scattering studies on actinide ‘115’ compounds are reviewed. The itinerant many-body f-electron system and cross over to the localized character are realized only in actinide system. Actinide ‘115’ family is very interesting, because we can grow high quality single crystals of many iso-structural compounds with different number and character of f electrons and valence d electrons. Variety of the ground state have been reported, e.g. paramagnetic, itinerant magnetism, and heavy fermion superconductivity in PuCoGa5. Very recently we have intensively studied the magnetic structure in UTGa5 and NpTGa5, These compounds exhibit a variety of the magnetic structure with A-, C-, G-type antiferromagnetic and ferromagnetic ordering and canted structure. NpFeGa5 exhibits an unusual magnetic anisotropy with the direction of the magnetic moment inclined about 25 degrees from the tetragonal basal plane. On the other hand, the localized compounds RRhIn5 (R: Tb, Ho, Dy, Nd) shows the antiferromagnetic structure with q=(1/2 0 1/2). The magnetic moment is parallel to the c-axis. An identical magnetic structure in rare earth compounds is a consequence of the localized nature of 4f electrons. We found that NpFeGa5, NpNiGa5, and NpRhGa5 exhibit 5f electronic transition between the low- and high-moment states associated with a change in the direction of the magnetic moment. The diverse magnetic ordering and the 5f electronic transition suggest that the orbital degree-of-freedom of itinerant 5f electrons may play important role for the physical properties in many body f-electron systems. Actually a localized model predicts the magnetic structure and the phase diagram with magnetic and quarupolar order parameters. A resonant X-ray scattering study is in progress, if the predicted antiferroquadrupole order coexists with the canting antiferromagnetic dipole order in NpNiGa5.

Keywords

actinidemagnetic propertiesneutron scattering
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 986: Symposium OO – Actinides 2006 – Basic Science, Applications and Technology , 2006 , 0986-OO02-04
Copyright
Copyright © Materials Research Society 2007

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