Altering the magnetic ordering of Fe3Ga4 via thermal annealing and hydrostatic pressure
Sharma, Vaibhav 1Naphy, Jared 2Bishop, Omar 1Bennett, Steven P. 3Prestigiacomo, Joseph 3Barua, Radhika 1Wilfong, Brandon 2Jamer, Michelle E.2
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作者信息
1. Virginia Commonwealth Univ
2. US Naval Acad
3. US Naval Res Lab
折叠
Abstract
The effects of post-synthesis annealing temperature on arc-melted samples of Fe3Ga4 has been studied to investigate changes in crystallographic and magnetic properties induced by annealing. Results show a significant trend in the evolution of the (incommensurate spin density wave) ISDW-FM (ferromagnetic) transition temperature as a function of the refined unit cell volume in annealed samples. Strikingly, this trend allowed for the tuning of the transition temperature down to room-temperature (300 K) whilst maintaining a sharp transition in temperature, opening the door to the use of Fe3Ga4 in functional devices. Crystallographic analysis through Rietveld refinement of high-resolution x-ray diffraction data has showed that arc-melted stoichiometric Fe3Ga4 is multi-phase regardless of annealing temperature with a minor phase of FeGa3 decreasing in phase fraction at higher annealing temperature. In order to validate the trend in ISDW-FM transition temperature with regard to unit cell volume, high pressure magnetometry was performed. This showed that the FM-ISDW 68 K) and ISDW-FM 360 K) transition temperatures could be tuned, increased and decreased respectively, linearly with external pressure. Thus, external pressure and the ensuing crystallographic changes minimize the temperature range of the stability of the ISDW pointing toward the importance of structural properties on the mechanism for the formation of the intermediate ISDW phase. These results show how this model system can be tuned as well as highlighting the need for future high-pressure crystallography and related single crystal measurements to understand the mechanism and nature of the intermediate ISDW phase to be exploited in future devices. Published by Elsevier B.V.
Key words
Magnetically ordered materials/Transition metal alloys and compounds/High-pressure/X-ray diffraction/Metamagnetism/PHASE-TRANSITIONS/SYSTEM/FIELD/CO(SXSE1-X)2/MOSSBAUER
NSTL
Elsevier