Synergistic effects of rare-earth doping on the magnetic properties of orthochromates: A machine learning approach

Abstract

Multiferroic materials, particularly rare-earth orthochromates (RECrO3), have garnered significant interest due to their unique magnetic and electric-polar properties, making them promising candidates for multifunctional devices. Although extensive research has been conducted on their antiferromagnetic (AFM) transition temperature (Neel temperature, TN), ferroelectricity, and piezoelectricity, the effects of doping and substitution of rare-earth (RE) elements on these properties remain insufficiently explored. In this study, convolutional neural networks (CNNs) were employed to predict and analyze the physical properties of RECrO3 compounds under various doping scenarios. Experimental and literature data were integrated to train machine learning models, enabling accurate predictions of TN, besides remanent polarization (Pr) and piezoelectric coefficients (d33). The results indicate that doping with specific RE elements significantly impacts TN, with optimal doping levels identified for enhanced performance. Furthermore, high-entropy RECrO3 compounds were systematically analyzed, demonstrating how the inclusion of multiple RE elements influences magnetic properties. This work establishes a robust framework for predicting and optimizing the properties of RECrO3 materials, offering valuable insights into their potential applications in energy storage and sensor technologies.

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