Enhanced coercivity and emergence of spin cluster glass state in 2D ferromagnetic material Fe3GeTe2

Two-dimensional (2D) van der Waals (vdW) magnetic materials with high coercivity and high \(T_\text{C}\) are desired for spintronics and memory storage applications. Fe\(_3\)GeTe\(_2\) (F3GT) is one such 2D vdW ferromagnet with a reasonably high \(T_\text{C}\), but with a very low coercive field, \(...

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Published inarXiv.org
Main Authors Bera, Satyabrata, Suman Kalyan Pradhan, Pal, Riju, Pal, Buddhadeb, Bera, Arnab, Kalimuddin, Sk, Das, Manjil, Deep Singha Roy, Afzal, Hasan, Pal, Atindra Nath, Mondal, Mintu
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 29.12.2022
Subjects
Antiferromagnetism
Antiphase boundaries
Clusters
Coercivity
Crystal defects
Ferromagnetic materials
Grain boundaries
Magnetic materials
Magnetic properties
Magnetism
Physics - Materials Science
Physics - Strongly Correlated Electrons
Pinning
Spin glasses
Spintronics
Transition temperature
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Summary:Two-dimensional (2D) van der Waals (vdW) magnetic materials with high coercivity and high \(T_\text{C}\) are desired for spintronics and memory storage applications. Fe\(_3\)GeTe\(_2\) (F3GT) is one such 2D vdW ferromagnet with a reasonably high \(T_\text{C}\), but with a very low coercive field, \(H_\text{c}\) (\(\lesssim\)100~Oe). Some of the common techniques of enhancing \(H_\text{c}\) are by introducing pinning centers, defects, stress, doping, etc. They involve the risk of undesirable alteration of other important magnetic properties. Here we propose a very easy, robust, and highly effective method of phase engineering by altering the sample growth conditions to greatly enhance the intrinsic coercivity (7-10 times) of the sample, without compromising its fundamental magnetic properties (\(T_\text{C}\simeq\)210K). The phase-engineered sample (F3GT-2) comprises of parent F3GT phase with a small percentage of randomly embedded clusters of a coplanar FeTe (FT) phase. The FT phase serves as both mosaic pinning centers between grains of F3GT above its antiferromagnetic transition temperature (\(T_\text{C1}\sim\)70~K) and also as anti-phase domains below \(T_\text{C1}\). As a result, the grain boundary disorder and metastable nature are greatly augmented, leading to highly enhanced coercivity, cluster spin glass, and meta-magnetic behavior. The enhanced coercivity (\(\simeq\)1~kOe) makes F3GT-2 much more useful for memory storage applications and is likely to elucidate a new route to tune useful magnetic properties. Moreover, this method is much more convenient than hetero-structure and other cumbersome techniques.
ISSN:2331-8422
DOI:10.48550/arxiv.2212.14221