Effects of the single-ion anisotropy on magnetic and thermodynamic properties of a ferrimagnetic mixed-spin (1, 3/2) cylindrical Ising nanowire

“…The coexistence of a negative exchange interaction between the core and the shell with the positive exchange interaction in the core and the shell separately is the main reason beyond the occurrence of the compensation phenomenon. It is noteworthy that similar phase diagrams have been observed in other nanosystems such as cylindrical ferrimagnetic nanotube with core-shell structure, [38] cylindrical Ising nanowire, [28,30] Ising nanoparticle, [45] rectangle Ising nanoribbon, [46] checkerboard square structure, [47] and three-layer system of hexagonal structure. [48] It should be noted that the first order and the critical end point are not studied in these references.…”

“…[24,[26][27][28][29] These studies are of great significance not only for the theoretical study of ferrimagnetic nanowires but also for experimental and practical applications. Indeed, Wang et al [30] studied the influence of single-ion anisotropy on the critical and hysteresis behavior of a mixed-spin (1, 3/2) cylindrical nanowire using Monte Carlo simulation. They have established the phase diagrams of the system in the temperature versus single-ion anisotropy plane, showing that they contain firstand second-order phase transition lines as well as a tricritical point for some cases of single-ion anisotropy.…”

Single‐Ion Anisotropy Effect on the Critical and Hysteresis Behaviors of a Mixed‐Spin (1, 3/2) Square Ising Nanowire

“…The coexistence of a negative exchange interaction between the core and the shell with the positive exchange interaction in the core and the shell separately is the main reason beyond the occurrence of the compensation phenomenon. It is noteworthy that similar phase diagrams have been observed in other nanosystems such as cylindrical ferrimagnetic nanotube with core-shell structure, [38] cylindrical Ising nanowire, [28,30] Ising nanoparticle, [45] rectangle Ising nanoribbon, [46] checkerboard square structure, [47] and three-layer system of hexagonal structure. [48] It should be noted that the first order and the critical end point are not studied in these references.…”

“…[24,[26][27][28][29] These studies are of great significance not only for the theoretical study of ferrimagnetic nanowires but also for experimental and practical applications. Indeed, Wang et al [30] studied the influence of single-ion anisotropy on the critical and hysteresis behavior of a mixed-spin (1, 3/2) cylindrical nanowire using Monte Carlo simulation. They have established the phase diagrams of the system in the temperature versus single-ion anisotropy plane, showing that they contain firstand second-order phase transition lines as well as a tricritical point for some cases of single-ion anisotropy.…”

Single‐Ion Anisotropy Effect on the Critical and Hysteresis Behaviors of a Mixed‐Spin (1, 3/2) Square Ising Nanowire

“…Mixed-spin Ising systems are often used as models to study ferrimagnetism. The occurrence of compensation in such systems has been verified in two-dimensional systems with a number of combinations of different spins (e. g. s = 1/2, 1, 3/2, 2, 5/2) [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22]. Some single-spin systems, such as layered magnets composed of stacked non-equivalent ferromagnetic planes, have also been effectively used to model ferrimagnets.…”

Ferrimagnetism and compensation temperature in spin-1/2 Ising trilayers

“…In our previous studies, the magnetic behaviors of various nano-systems have been studied by means of MC simulation, such as the zigzag graphene nanoribbon (GRNs) [43], ferrimagnetic mixed-spin Ising nanoisland [44], nanowires [45], nanotubes [46], graphene-like nanoisland bilayer [47], nanoparticles [48] and so on. However, little attention has been applied to the dynamic magnetic properties of Ising graphene-like monolayer under external oscillating magnetic field.…”

Dynamic magnetic properties of Ising graphene-like monolayer