Your search keyword '"FERRIMAGNETIC materials"' showing total 14 results

1. Compensation temperature and hysteresis behaviors of the ferrimagnetic bilayer zigzag graphyne nanoribbon with RKKY interaction.

Author

Lv, Jia-qi, Zhang, Fan, Wang, Wei, and Li, Bo-chen

Subjects

*FERRIMAGNETIC materials, *EXCHANGE interactions (Magnetism), *HYSTERESIS, *MONTE Carlo method, *HYSTERESIS loop, *ISING model

Abstract

In this study, a bilayer zigzag graphyne nanoribbon with RKKY interaction is described using a ferrimagnetic mixed-spin (2, 5/2) Ising model. The compensation behaviors and hysteresis characteristics of the system generated by various physical parameters, such as crystal fields of sublattices, interlayer exchange coupling and the intralayer exchange coupling are explored using Monte Carlo simulation. In the research results, we found that among the 30 possible spin configurations that may occur in the ground state of the system, only 21 spin configurations are stable. At the same time, under certain parameters, the system exhibit interesting behaviors such as compensation phenomena and multi-loop hysteresis. This can provide a theoretical reference for multi-state magnetic recording. • Ising model and Monte Carlo method were used to study the bilayer zigzag graphyne nanoribbon. • The effect of RKKY interaction on the magnetic properties of the graphyne was investigated. • The ground-state phase diagram, magnetization, magnetic susceptibility were obtained. • Phase diagrams and hysteresis loop of the system were presented. • Interesting behaviors of compensation temperatures and multi-loop hysteresis were found under certain parameters. [ABSTRACT FROM AUTHOR]

Published

2024

2. Electronic and Magneto-Electric properties of YFeO3.

Author

Zahrae Kassimi, Fatima, Zaari, Halima, Benyoussef, Abdelilah, and El Kenz, Abdallah

Subjects

*POLARIZATION (Electricity), *MAGNETIC transitions, *TRANSITION temperature, *ISING model, *CRITICAL temperature, *HEISENBERG model, *FERRIMAGNETIC materials

Abstract

• YFeO 3 have been studied with GGA and GGA+U reveal a semi-conductor and an Antiferromagnetic type-G behavior. • Magnetic anisotropy results for both approximations show that easy axis magnetization for YFeO 3 is along the c-axis. • Evaluation of the electric polarization and the magnetic transition temperature of the orthorhombic YFeO 3 has done. In this study, we have thoroughly investigated the electronic, magnetic, and electrical properties of yttrium orthoferrite using density functional theory (DFT) within the generalized gradient approximation (GGA) and the (GGA + U) approach, which incorporates the Hubbard term (U). Both approximations consistently reveal a semiconductor behavior and an antiferromagnetic behavior of type-G between the iron (Fe) ions. To delve deeper into the magnetic interactions within YFeO 3 , we have proposed a physical model. This model allows us to calculate the magnetic exchange coupling and magnetic anisotropy parameters through DFT calculations. Additionally, we have conducted computations to determine the electric polarization. Our results have shown that the electric polarization in YFeO 3 is exclusively derived from electronic polarization. We have also explored the relationship between the direction of electric polarization and the easy-axis magnetization. In our investigation, we found that both the electric polarization and easy-axis magnetization align along the c-axis in both approximations. Furthermore, we have examined the influence of the Hubbard term on the direction of polarization. To assess the magnetic temperature transition, we employed Monte Carlo simulations using the Ising model. The critical temperature, denoted as T N , obtained with the GGA approximation is found to be 726.66 K. Remarkably, this value closely matches the experimental critical temperature when compared to the critical temperature obtained with the GGA + U approximation. [ABSTRACT FROM AUTHOR]

Published

2023

3. Exchange bias, reentrant phenomena and compensation behavior in a core–shell ferrimagnetic nanotube: Theoretical investigation of a disordered system's magnetic and energetic behavior within the framework of effective field theory approach.

Author

Arbaoui, A., AhlLaamara, R., Drissi, L.B., and Htoutou, K.

Subjects

*FERRIMAGNETIC materials, *NANOTUBES, *PHASE transitions, *HELMHOLTZ free energy, *HYSTERESIS loop, *MAGNETIC susceptibility, *TRANSITION temperature

Abstract

We studied the compensation behavior, the reentrant phenomena characterizing first order phase transitions, and the exchange bias effect manifested by asymmetric hysteresis loops for a core–shell nanotube with mixed spin (1 , 3 / 2) by combining both the effective field theory and the probability distribution technique. Since our system is intended to be disordered on the shell, a uniform distribution for the exchange anisotropy proposed. Among the interesting results are the compensation behavior in the ideal and disordered cases, where we noticed a critical behavior manifested by total magnetization persistence, the compensation behavior accompanied by the reentrant phenomena, as well as the multi-loops behavior, exchange bias effect, and magnetic susceptibility. Internal energy, Helmholtz free energy, and double peak specific heat are also used to invoke the energetic aspect. • Ferrimagnetic systems' magnetic properties. • Disordered magnetic systems. • Reentrant magnetic phenomena. • Multi-hysteresis loops and hysteresis loops. • First order phase transition and compensation temperature. [ABSTRACT FROM AUTHOR]

Published

2023

4. Compensation temperatures and hysteresis loops of the ferrimagnetic bilayer kagome lattice with RKKY interaction.

Author

Xu, Shi-qi, Wang, Wei, Xu, Zhen-yao, Lv, Jia-qi, and Li, Bo-chen

Subjects

*FERRIMAGNETIC materials, *HYSTERESIS loop, *MONTE Carlo method, *ISING model, *PHASE diagrams, *CRITICAL temperature, *BILAYER lipid membranes, *TEMPERATURE

Abstract

In this study, a bilayer Kagome lattice with RKKY interaction is described using a ferrimagnetic mixed spin-3/2 and spin-2 Ising model. Interesting compensation temperature and hysteresis loops of the system generated by various physical parameters, such as the crystal fields of sublattices (D a , D b), the interlayer exchange coupling (J R) and the intralayer exchange coupling (J b) are explored using Monte Carlo simulation. The results demonstrate that the compensation temperature (T comp), weaker D a and J b , and stronger D b , are favourable for the emergence of the compensation temperatures. Besides, under certain physical parameters, the system may exhibit triple-loop hysteresis behavior and multiple magnetization plateaus. • A ferrimagnetic mixed-spin (3/2, 2) Ising model on the bilayer Kagome lattice with RKKY interaction was proposed. • The effects of the crystal field, exchange coupling and non-magnetic layer were studied. • Magnetization, partial magnetization, and susceptibility were discussed. • Phase diagrams of the critical and compensation temperatures were obtained. • Interesting multi-loop hysteresis characteristics and magnetization plateaus were found. [ABSTRACT FROM AUTHOR]

Published

2023

5. Insights into magnetic behaviors of an Ising graphene ladder-type chain structure applied in an external magnetic field.

Author

Lv, Dan, Li, Hui-yi, Zhang, De-zhi, and Li, Bo-chen

Subjects

*FERRIMAGNETIC materials, *MAGNETIC fields, *MONTE Carlo method, *GRAPHENE, *MAGNETIC susceptibility, *ISING model

Abstract

We proposed a ferrimagnetic mixed-spin (1, 3/2) Ising model to study the magnetic behaviors of a graphene ladder-type chain structure by means of Monte Carlo simulation. Induced by different physical parameters, the system can display interesting magnetic behaviors such multiple saturation magnetization values, double-peak susceptibility curves, and multi-cycle hysteresis loops. The results illustrate that crystal-field, exchange coupling and external magnetic field show significant impacts on the magnetic properties of the system. • A mixed-spin (1, 3/2) Ising model was proposed to describe a ferrimagnetic graphene ladder-type chain structure. • Magnetization, magnetic susceptibility, and internal energy were studied by Monte Carlo method. • The phase diagrams of the blocking temperature in three-dimensional space was given. • Multi-cycle hysteresis behaviors were discovered caused by various parameters. [ABSTRACT FROM AUTHOR]

Published

2023

6. Effective-field theory with the probability distribution technique for a spin-3/2 core and spin-2 shell Ising nanowire: Thermodynamic properties and hysteresis behaviors.

Author

Htoutou, K. and Arbaoui, A.

Subjects

*NANOWIRES, *FERRIMAGNETIC materials, *DISTRIBUTION (Probability theory), *HYSTERESIS, *HYSTERESIS loop, *ISING model, *MAGNETIC fields

Abstract

The probability distribution technique, exploited within the framework of effective field theory and the Ising model, was used to study the magnetic and thermal properties of a nanowire assimilated to a hexagonal shaped system of a core–shell structure and with mixed spins (3 / 2 , 2) , respectively. The coupling between core and shell is ferrimagnetic. Under certain physical parameter values, the nanowire exhibits the compensation behavior. The hysteresis behavior was investigated in the presence of an external magnetic field by magnetizing and demagnetizing the nanowire, as well as the effects of single ion anisotropy, ferrimagnetic exchange interactions and temperature on hysteresis loops. The dependence of the shapes of loops on the physical parameters of the system has been elucidated. At low temperatures, the nanowire exhibits triple, quadruple, quintuple, sextuple, septuple and nonuple hysteresis loop behaviors, which have important technological applications. Furthermore, the thermodynamic properties of the nanowire was also studied by evaluating the susceptibility, the internal energy and specific heat for a variety of system physical parameters. [ABSTRACT FROM AUTHOR]

Published

2022

7. Computational study of magnetic properties of L10 ordered FeNi and FePt binary alloys.

Author

Obeidat, Abdalla, Aladerah, Bilal, and Qaseer, Mohammad-Khair

Subjects

*BINARY metallic systems, *MAGNETIC properties, *CRITICAL temperature, *MONTE Carlo method, *SPECIFIC heat, *MAGNETIC susceptibility, *FERRIMAGNETIC materials

Abstract

• The critical temperature of FeNi and FePt alloys using Heisenberg interaction is closer to the experimental value than the Ising interaction. • The FeNi and FePt alloys prefer a ferromagnetic phase over the ferrimagnatic phase. • The Ising interaction predicts higher critical temperature for the FeNi alloy than the Heisenberg interaction. • The Heisenberg interaction predicts higher critical temperature for the FePt alloy than the Ising interaction. A Monte Carlo simulation has been used to explore the magnetic properties of L1 0 ordered FeNi and FePt binary alloys. Our Hamiltonians include Heisenberg interaction or Ising interaction. Our calculations of variations of specific heat C v , magnetic susceptibility χ and the magnetization M with the temperature T showed that predicted critical temperature for ferromagnetic phase is very close to the experimental values for these alloys. Also, thermal hysteresis loops, magnetic remanence, and the coercive field have been calculated. Moreover, the magnetic properties of the ferrimagnetic phase are presented. [ABSTRACT FROM AUTHOR]

Published

2022

8. Phase diagrams and compensation behaviors of a mixed Spin-(3/2, 1) Ising-Type Ferrimagnet: Monte Carlo investigation.

Author

Elidrysy, A., Harir, S., Zouhair, A., and Y.Boughaleb

Subjects

*FERRIMAGNETIC materials, *PHASE diagrams, *MAGNETIC crystals, *MONTE Carlo method, *ISING model, *MAGNETIC fields

Abstract

• The mixed spin Ising model is generally used as a modeling tool to study ferrimagnetism. • Monte Carlo simulation to study the critical and the compensation behaviors of a cubic lattice considering a mixed spin- 3/2 and spin-1 Ising ferrimagnetic model. • The presence of crystal and external magnetic fields is not sufficient to generate the compensation phenomenon in a mixed spins. In this study, we perform Monte Carlo simulations to study the magnetic properties of a mixed Ising model on a cubic lattice where spins S i A = 1 and σ J B = 3/2 are located in sublattice A and B, respectively. The proposed Hamiltonian includes coupling to nearest-neighbors interactions, next-nearest-neighbors interactions, crystal fields D S and D σ and external magnetic field h. We perform exact ground-state calculations for our model. The obtained results show the behavior of the critical temperature with the presence of the compensation temperatures under a certain range of parameters. Particularly, we found that the existence of compensation temperatures depends on the strength of the coupling to the next nearest neighbors between the S i A spins and between the σ J B spins, and it appears in a certain range of values of the external magnetic and crystal field of different spins. [ABSTRACT FROM AUTHOR]

Published

2022

9. Anomalous thermodynamics in a mixed spin-1/2 and spin-1 hexagonal nanowire system.

Author

Pimenta, R.A., Rojas, O., and de Souza, S.M.

Subjects

*THERMODYNAMICS, *SPONTANEOUS magnetization, *ISING model, *TRANSFER matrix, *SPECIFIC heat, *FERRIMAGNETIC materials, *NANOWIRES

Abstract

The mixed spin-1/2 Ising model and spin-1 Blume–Capel model in an hexagonal nanowire structure under the presence of crystal field is considered. The free energy is obtained through the transfer matrix technique, which is solved numerically. Our main result lies in the presence of pseudo-transition in low temperature region near the ferrimagnetic/ferromagnetic boundary, due to the influence of a crystal field. The evidence of a pseudo-transition is observed in several quantities. Free energy first derivative quantities like entropy and internal energy show an abrupt but continuous jump, whereas quantities associated with second derivatives of the free energy like the specific heat exhibit a strong sharp peak, quite similar to a second order phase transition. We also investigate magnetization patterns and do not find evidence of spontaneous magnetization. Nevertheless, assuming a small magnetic field, we can induce a magnetization which resembles a spontaneous magnetization at a pseudo-critical temperature. • Zero temperature phase diagram of the mixed spin-1/2 and spin-1 hexagonal nanowire system. • High precision numerical diagonalization of the transfer matrix. • High precision numerical thermodynamics. • Absence of finite temperature phase transition in the mixed spin-1/2 and spin-1 hexagonal nanowire system. [ABSTRACT FROM AUTHOR]

Published

2022

10. Critical and compensation temperature in a ferrimagnetic mixed spin Ising trilayer nano-graphene superlattice.

Author

Boubekri, Abderrazak, Elmaddahi, Zakaria, Farchakh, Abdeslam, and El Hafidi, Mohamed

Subjects

*FERRIMAGNETIC materials, *CRITICAL temperature, *HYSTERESIS loop, *ISING model, *CRITICAL point (Thermodynamics), *MAGNETIC properties, *ANISOTROPY

Abstract

An effective field method has been employed to study the magnetic properties of a ferrimagnetic mixed-spin Ising trilayer nanographene structure. The system is formed by alternate layers of two different spins atoms A (spin-1) and B (spin-½) arranged in a particular fashion A – B – A for which the nearest-neighbor spins of each layer are coupled ferromagnetically (J A and J B), whereas the cross atom interaction A - B (interlayer) is antiferromagnetic (J AB). We examined the effects of interlayer (or intra-layer) exchange coupling and single-ion anisotropy on the magnetization curves of the system. We found that the antiferromagnetic inter-layers (J AB < 0) coupling and the single-ion anisotropy have a dominant factor in the occurrence of the single or the double compensation temperature. We also deeply examined the occurrence of hysteresis loops and their various unusual forms. The results obtained are discussed in detail as a function of the main parameters of the magnetic Hamiltonian. Finally, we noticed that our results are in line with other recently reported theoretical and numerical studies. • Ferrimagnetic spin mixed with nano-graphene trilayer Ising model on effective field approach has been considered. • Effects of Intra- and inter-layers exchange couplings, as well as single-ion anisotropy have been analyzed. • One or more compensation points can be obtained under special choice of intrinsic parameters. • The shape and the multi-windows hysteresis loops can be controlled through exchange or single-ion anisotropy. • Application of synthetic ferrimagnetic multilayers are outlined. [ABSTRACT FROM AUTHOR]

Published

2022

11. Magnetic properties of the ferrimagnetic triangular nanotube with core–shell structure: A Monte Carlo study.

Author

Gharaibeh, Maen, Alqaiem, Samah, Obeidat, Abdalla, Al-Qawasmeh, Ahmad, Abedrabbo, Sufian, and Badarneh, Mohammad H.A.

Subjects

*FERRIMAGNETIC materials, *MAGNETIC properties, *MAGNETIC transitions, *MAGNETIC anisotropy, *HYSTERESIS loop, *NANOTUBES, *MONTE Carlo method

Abstract

Monte Carlo simulation has been employed to investigate the magnetic properties and phase diagrams of ferrimagnetic mixed-spin (1 / 2 , 1) triangular Ising nanotube with core–shell structure. In particular, the effect of the exchange couplings and the temperature on the magnetic and thermodynamic properties, hysteresis loops, and the compensation temperature have been discussed in detail. Moreover, the effects of the single-ion anisotropy and external magnetic field have been examined. The threshold values of the exchange couplings and single-ion anisotropy have been found, determining whether the system exhibits a compensation temperature. We have found that the appearance of the compensation temperature is strongly linked with the system parameters. Moreover, we have obtained the double and triple hysteresis loops for certain physical parameters in the magnetic system. [ABSTRACT FROM AUTHOR]

Published

2021

12. The magnetic properties and hysteresis loops of mixed spin-(3/2,2) hexagonal Ising nanowire system with alternate layers.

Author

Nmaila, B., Htoutou, K., Drissi, L.B., and Laamara, R. Ahl

Subjects

*FERRIMAGNETIC materials, *MAGNETIC hysteresis, *HYSTERESIS loop, *MAGNETIC properties, *NANOWIRES, *MONTE Carlo method, *SPECIFIC heat, *COUPLING constants

Abstract

In this paper, we have examined in detail the behavior of magnetic properties, hysteresis loops, and compensation phenomenon of a ferrimagnetic mixed spin- (3 ∕ 2 , 2) hexagonal Ising nanowire with alternate layers within the Monte Carlo method based on the Metropolis algorithm. The effect of longitudinal crystal field and exchange coupling constants on the total and the sublattice magnetizations, susceptibilities, specific heat, internal energy, as well as hysteresis loops are investigated for particular parameters. The obtained résults showed different interesting magnetic phenomena, such as seven and triple hysteresis loops at low temperatures, and one or double compensation temperatures under certain parameter values. Our outcomes are also compared with various experimental and theoretical studies. • A hexagonal mixed spin-3/2 and spin-2 Ising ferrimagnetic nanowire with alternate layers, within Monte Carlo simulation techniques. • The effects of the longitudinal crystal fields, the exchange coupling constant, and the temperature on the thermodynamic and magnetic properties and the hysteresis loops were examined in detail. • The seven and triple hysteresis loops at low temperatures, and double compensation temperatures under certain physical parameters. [ABSTRACT FROM AUTHOR]

Published

2021

13. Thermodynamic properties and hysteresis loops in a hexagonal core-shell nanoparticle.

Author

Wang, Si-yu, Lv, Dan, Liu, Zhen-yu, Wang, Wei, Bao, Jia, and Huang, Han

Subjects

*FERRIMAGNETIC materials, *HYSTERESIS loop, *MONTE Carlo method, *ISING model, *MAGNETIC fields, *CRITICAL temperature, *HYSTERESIS

Abstract

We applied Monte Carlo simulation to investigate the thermodynamic properties and hysteresis loops of the hexagonal core-shell nanoparticle described by a ferrimagnetic mixed-spin (3/2, 5/2) Ising model. The results revealed the significance of the single-ion anisotropy, exchange coupling, external magnetic field in dominating various thermodynamic quantities and hysteresis loops. We obtained the variation of the critical temperature with various parameters. Under certain parameter conditions, the system may exhibit rich multiple-loop hysteresis behaviors, depending on the competition among the physical parameters. An Ising model of nanoparticle with hexagonal core-shell structure is proposed. The multiple profiles and saturation values of the magnetization are discovered in the system. [Display omitted] • A ferrimagnetic hexagonal core-shell nanoparticle was proposed under an external magnetic field. • Magnetization, susceptibility, and internal energy were discussed by Monte Carlo simulation. • The compensation temperature was found under the effect of single-ion anisotropy. • Multiple-loop hysteresis behaviors were discovered due to the competition among different physical parameters. [ABSTRACT FROM AUTHOR]

Published

2021

14. Magnetic and thermodynamic behaviors of the graphene-like quantum dots: A Monte Carlo study.

Author

Sun, Lei, Wang, Wei, Lv, Dan, Gao, Zhong-yue, Li, Qi, and Li, Bo-chen

Subjects

*FERRIMAGNETIC materials, *QUANTUM dots, *MONTE Carlo method, *HYSTERESIS loop, *MAGNETIC fields, *ISING model

Abstract

• The graphene-like quantum dots with mixed-spin (3/2, 5/2) have been investigated. • The magnetic and thermodynamic behaviors have been explored. • The turnover phenomenon has been found. • The triple-loop behavior has been observed. Based on the Monte Carlo simulation, we have investigated the magnetic and thermodynamic behaviors of the graphene-like quantum dots described by a ferrimagnetic mixed-spin (3/2, 5/2) Ising model. The curves of the magnetization, magnetic susceptibility, internal energy and the specific heat as a function of temperature have been given under various physical parameters. The interesting turnover phenomenon has been found owing to the competition between the crystal field and temperature. It is found that the value of the blocking temperature increases with decreasing the crystal field or increasing the exchange coupling and external magnetic field. We have also investigated the hysteresis loops and found the impossibility of the triple-loop hysteresis behavior for certain parameters. The area of the hysteresis loops can be improved by increasing the exchange coupling and decreasing the absolute values of the crystal field and temperature. [ABSTRACT FROM AUTHOR]

Published

2021