Testing the generalized conjugate field formalism in the kinetic Ising model with nonantisymmetric magnetic fields: A Monte Carlo simulation study
Abstract
We have performed Monte Carlo simulations for the investigation of dynamic phase transitions on a honeycomb lattice which has garnered a significant amount of interest from the viewpoint of tailoring the intrinsic magnetism in two-dimensional materials. For the system under the influence of time-dependent magnetic field sequences exhibiting the half-wave anti-symmetry, we have located a second order dynamic phase transition between dynamic ferromagnetic and dynamic paramagnetic states. Particular emphasis was devoted for the examination of the generalized conjugate field formalism previously introduced in the kinetic Ising model [blueQuintana and Berger, Phys. Rev. E 104, 044125 (202); Phys. Rev. E 109, 054112] black. Based on the simulation data, in the presence of a second magnetic field component with amplitude H2 and period P/2, the half-wave anti-symmetry is broken and the generalized conjugate field formalism is found to be valid for the present system. However, dynamic scaling exponent significantly deviates from its equilibrium value along with the manifestation of a dynamically field polarized state for non-vanishing H2 values.
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