1. Reconstructing phase-resolved hysteresis loops from first-order reversal curves
- Author
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Randy K. Dumas, Kai Liu, Julius de Rojas, Joseph E. Davies, Peyton D. Murray, and Dustin A. Gilbert
- Subjects
Materials science ,Magnetometer ,Science ,Phase (waves) ,FOS: Physical sciences ,Bioengineering ,02 engineering and technology ,01 natural sciences ,Characterization and analytical techniques ,Article ,law.invention ,physics.data-an ,law ,Magnetic properties and materials ,0103 physical sciences ,cond-mat.mes-hall ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,Anisotropy ,Saturation (magnetic) ,010302 applied physics ,Exchange spring magnet ,Condensed Matter - Materials Science ,Multidisciplinary ,Condensed matter physics ,Condensed Matter - Mesoscale and Nanoscale Physics ,Materials Science (cond-mat.mtrl-sci) ,Coercivity ,021001 nanoscience & nanotechnology ,Magnetic hysteresis ,cond-mat.mtrl-sci ,Hysteresis ,Physics - Data Analysis, Statistics and Probability ,Ferromagnetism ,Medicine ,0210 nano-technology ,Data Analysis, Statistics and Probability (physics.data-an) - Abstract
The first order reversal curve (FORC) method is a magnetometry based technique used to capture nanoscale magnetic phase separation and interactions with macroscopic measurements using minor hysteresis loop analysis. This makes the FORC technique a powerful tool in the analysis of complex systems which cannot be effectively probed using localized techniques. However, recovering quantitative details about the identified phases which can be compared to traditionally measured metrics remains an enigmatic challenge. We demonstrate a technique to reconstruct phase-resolved magnetic hysteresis loops by selectively integrating the measured FORC distribution. From these minor loops, the traditional metrics—including the coercivity and saturation field, and the remanent and saturation magnetization—can be determined. In order to perform this analysis, special consideration must be paid to the accurate quantitative management of the so-called reversible features. This technique is demonstrated on three representative materials systems, high anisotropy FeCuPt thin-films, Fe nanodots, and SmCo/Fe exchange spring magnet films, and shows excellent agreement with the direct measured major loop, as well as the phase separated loops.
- Published
- 2021