Title :
Spin-Phonon Coupling in PrMn2O5 Nanorods
Author :
Ting-Wei Hsu ; Chung-Cheun Yang ; Huo-Yen Chen ; Hsi-Sheng Hsia ; Kuen-Song Lin
Author_Institution :
Dept. of Phys., Chung Yuan Christian Univ., Chungli, Taiwan
Abstract :
PrMn2O5 nanorods with five axial ((LC)) x radial lengths of 63 nm x 25 nm, 150 nm x 25 nm, 152 nm x 29 nm, 259 nm x 86 nm, and 262 nm x 87 nm were fabricated by the hydrothermal method. Experiments on magnetic susceptibility demonstrate incommensurate antiferromagnetic (ICAFM) (TN) and ICAFM-to-commensurate antiferromagnetic (TN,) ordering at 43 and 20 K, respectively, in the samples with (LC) ≤ 259 nm. At (LC) = 262 nm, both TN and TN, are shifted to higher temperatures and the samples exhibit magnetic correlation from 150 K. Experimentally obtained M-H curves demonstrate that only the sample with (LC) = 262 nm exhibits a hysteresis loop. Raman spectra obtained at various temperatures reveal that in only the sample with (LC) = 262 nm does the Ag + B1g mode exhibit a large Raman shift until the sample is cooled to 150 K. The distinctiveness of the (LC) = 262 nm sample arises from annealing. This treatment reduces the barrier to magnetic ordering that is caused by defects and promotes spin-phonon coupling at high temperatures.
Keywords :
Raman spectra; antiferromagnetic materials; commensurate-incommensurate transformations; high-temperature effects; magnetic hysteresis; magnetic susceptibility; magnetic transitions; multiferroics; nanofabrication; nanomagnetics; nanorods; praseodymium compounds; spin-phonon interactions; ICAFM-to-commensurate antiferromagnetic ordering; M-H curves; PrMn2O5; Raman shift; Raman spectra; annealing; high-temperature spin-phonon coupling; hydrothermal method; hysteresis loop; incommensurate antiferromagnetic ordering; magnetic correlation; magnetic susceptibility; nanorods; Annealing; Couplings; Magnetic domains; Magnetic hysteresis; Magnetic resonance imaging; Magnetic separation; Magnetoelectric effects; Magnetic; multiferroic; nanorod; size effect; spin-phonon;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2014.2326953
