Magnetic characteristics of the ferrimagnetic bilayer MXene-like nanostructure with interlayer exchange interactions: Monte Carlo study

This study explores the magnetic properties of Borospherene-like and Buckminsterfullerene-like lattices using Monte Carlo simulation, revealing novel behaviors. The dependency of blocking temperature (TB) on external magnetic field strength (H), linear coupling interaction (J), and biquadratic coupling interaction (K) was studied and compared between the two lattice types. Additionally, the evolution of coercive field (HC) with J and K parameters for both lattice types was analyzed. This study highlights the unique magnetic responses of these lattices and their potential applications in magnetic research and nanotechnology.

mentioning

confidence: 99%

Exploring Magnetic Attributes: Borospherene-Like and Buckminsterfullerene-Like Lattices in Monte Carlo Simulations

Fadil,

Raorane,

Kabouchi

et al. 2024

“…Investigating bilayer MXene-like nanostructure, Monte Carlo studies offer insights into the complex interplay between magnetic layers, shedding light on their magnetic properties. 26 Transitioning to iron nanoparticles, Monte Carlo and molecular-statics simulations provide valuable insights into both structural and magnetic properties, offering a comprehensive understanding of nanoparticle behavior. 27 Additionally, Monte Carlo simulations uncover the magnetocaloric characteristics of a diluted graphdiyne, contributing to the development of advanced magnetic materials.…”

mentioning

confidence: 99%

Investigation of the Magnetic Features of the Fullerene-Dimer-Like Nanostructure (C ₆₀)₂: A Monte Carlo Study

Kabouchi,

Fadil,

El Fdil

et al. 2024

Self Cite

The current investigation employs Monte Carlo simulations to explore the magnetic features of a Fullerene-dimer-like nanostructure (C60)2 characterized by the spin σ-1. It explores how the coupling interaction Jσ, the biquadratic parameter K, the external magnetic H and the crystal D fields influence the thermal and magnetic features of the nanostructure, particularly the blocking temperature (TB). The results also highlight the dependence of hysteresis cycles and the coercive magnetic field Hc on the values of Jσ, K, and D, with significant variations at lower temperatures. The findings indicate the distinctive magnetic behavior of the Fullerene-dimer-like nanostructure (C60)2 potentially useful in various technological applications.

“…The creation and study of two-dimensional (2D) materials are highly valued in materials science their exceptional physical properties and wide-ranging application possibilities, as evidenced by numerous studies. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15] These materials are recognized for their exceptional thickness and strength, playing a crucial role in driving advancements in different fields. Specifically, they are fundamental in driving innovation in areas such as electronics, 16 spintronics, 17 solar cell technology, 18 rechargeable batteries, 18 and the development of energy storage solutions.…”

mentioning

confidence: 99%

Exploring Dielectric Responses in Nano Kagome Bilayers Through Monte Carlo Simulations

Eraki,

Kabouchi,

Fadil

et al. 2024

Self Cite

This study uses Monte Carlo simulations to investigate the dielectric properties of a mixed nano Kagome lattice. The investigation explores the effects of exchange coupling interactions, temperature variations, and the crystalline field on blocking temperature and hysteresis loop characteristics. By conducting in-depth analysis and simulation, the study aims to provide a nuanced understanding of the dielectric behavior within a mixed nano Kagome lattice. The dielectric response in a nano Kagome lattice has potential applications in spintronics and nanotechnology.