Machine learning-based prediction of FeNi nanoparticle magnetization
F Williamson and N Naciff and C Catania and G dos Santos and N Amigo and
EM Bringa, JOURNAL OF MATERIALS RESEARCH AND TECHNOLOGY-JMR&T, 33,
5263-5276 (2024).
DOI: 10.1016/j.jmrt.2024.10.142
This work proposes a computationally efficient approach for estimating
the magnetization of Fe0.7Ni0.3 body-centered cubic (bcc) nanoparticles
(NPs) at room temperature using machine-learning algorithms, in terms of
the average magnetic moment per atom, . The magnetization data of
isolated NPs were generated using atomistic spin dynamics (ASD)
simulations for various nanoparticle shapes (cubes, spheres, octahedra,
cones, cylinders, ellipsoids, flakes, and pyramids, with or without
nanovoids) and FeNi distributions (random, core-shell, onion, sandwich,
and Janus with different boundary planes). More than 1600 NPs were
created and split into training and testing sets (70%-30% split), with
features including the number of Ni/Fe surface and core atoms, potential
energy distributions, pair correlation functions, and coordination
distributions. Several machine-learning algorithms, including Random
Forest (RF), Elastic Net, Support Vector Regression (SVR), and Gradient
Boosting Regression (CatBoost), were applied to predict the average
magnetic moment per atom of these NPs. The best-performing models,
CatBoost and RF, achieved R-2 scores of up to 0.86, demonstrating their
accuracy in predicting NP magnetization. Feature analysis highlighted
the significance of the interface between Fe and Ni clusters, Fe-Fe
interactions, and the presence of Fe on the surface as critical
contributors to overall magnetization. Random alloy spherical NPs
without porosity exhibited the highest similar to 1.6 mu(B) due to
reduced Ni-Ni interactions. Applying machine-learning methods
significantly reduces computational time and memory requirements
compared to traditional ASD simulations. This allows for rapid
prediction of NPs with desired magnetic properties, making them suitable
for various technological applications.
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