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Dynamic magnetic properties and magnetocaloric effect of a bilayer graphdiyne-like nanoribbon

Wei Wang, Xing-Guo Wang, Bo-chen Li, Zhen-yao Xu

2025Physica Scripta9 citationsDOI

Abstract

Abstract This study conducts Monte Carlo simulation to investigate the dynamic magnetic, thermodynamic properties and magnetocaloric effect of a bilayer graphdiyne-like nanoribbon described by a ferrimagnetic mixed-spin (1/2, 5/2) two-dimensional Ising model applied in a time-dependent magnetic field. The results show that a strong crystal field can reduce critical temperature T C , and an enhanced exchange coupling can increase T C . Extending the oscillation period of the magnetic field from 50 to 1000 also results in a decline in T C , and the peak value of magnetic entropy change reaches its maximum when the oscillation period is 200. The peak value of adiabatic entropy change − Δ S m fluctuates between 0.061 and 0.0738, and is proportional to the variation range of the external magnetic field. As the range in the amplitude of the oscillating field increases from 0 to 2.0, the − Δ S m peak rises significantly. Phase diagrams between the critical temperature and various parameters were also constructed.

Topics & Concepts

Magnetic refrigerationCondensed matter physicsFerrimagnetismMaterials scienceAmplitudeMagnetic fieldAdiabatic processOscillation (cell signaling)BilayerIsing modelMonte Carlo methodCoupling (piping)Phase transitionFerromagnetismAtmospheric temperature rangePhase (matter)Magnetic hysteresisCoupling parameterEntropy (arrow of time)Field (mathematics)Mean field theoryPhysicsRange (aeronautics)Transition temperatureExchange biasTheoretical and Computational PhysicsChemical and Physical Properties of MaterialsGraphene research and applications
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