Abstract
The intermetallic compound Nd5Fe17 has potentially important magnetic properties and is being investigated as a possible permanent magnetic material. As with many other rare-earth transition metal compounds, this phase can absorb significant quantities of H(D) and lesser amounts of N. Gravimetric measurement indicate that ∼14-16H(D) atoms can be absorbed per formula unit leading to roughly a 20% increase in saturation magnetization and Curie temperature. We have carried out powder neutron diffraction studies to determine the location of D atoms in a sample of Nd5Fe17 containing approximately 15.5D/f.u. The large, complex unit cell of Nd5Fe17, with 21 crystallographically distinct sites per unit cell makes this a daunting task, but the diffraction diagram shows dramatic changes with D uptake, suggesting that such a determination is possible. We have identified about 15 sites fully or partially occupied by D. The majority of these are tetrahedral sites, as expected. Among remaining sites, one is octahedral site and others show unusual environments with 5 metal neighbors. A few D atoms show anomalously short bonds to neighboring metal atoms suggesting that their positions may not be entirely correct. However, elimination of these atoms from the model, one by one, leads to relaxation of other positions, and in some cases, other bonds become unacceptably short. In addition, some D atoms show very short bonds to neighboring D sites. In these cases the sites are found to be only partially occupied, suggesting that the adjacent sites cannot be simultaneously occupied.
Recommended Citation
Z. Chu et al., "A Neutron Diffraction Study of the Deuterium Site Occupancy in Nd5Fe17D15.5," IEEE Transactions on Magnetics, vol. 37, no. 4 I, pp. 2172 - 2175, Institute of Electrical and Electronics Engineers, Jan 2001.
The definitive version is available at https://doi.org/10.1109/20.951115
Department(s)
Physics
Keywords and Phrases
Deuterium absorption; Interstitial compounds Nd Fe 5 17; Neutron diffraction; Permanent magnet phases
International Standard Serial Number (ISSN)
0018-9464
Document Type
Article - Journal
Document Version
Citation
File Type
text
Language(s)
English
Rights
© 2024 Institute of Electrical and Electronics Engineers, All rights reserved.
Publication Date
01 Jan 2001
Comments
National Science Foundation, Grant DMR-9 614 596