Lifshitz scaling effects on the holographic paramagnetic-ferromagnetic phase transition

We disclose the effects of Lifshitz dynamical exponent z on the properties of holographic paramagnetic-ferromagnetic phase transition in the background of Lifshitz spacetime. To preserve the conformal invariance in higher dimensions, we consider the Power-Maxwell (PM) electrodynamics as our gauge field. We introduce a massive 2-form coupled to the PM field and perform the numerical shooting method in the probe limit by assuming the PM and the 2-form fields do not back-react on the background geometry. The obtained results indicate that the critical temperature decreases with increasing the strength of the power parameter q and dynamical exponent z. Besides, the formation of the magnetic moment in the black hole background is harder in the absence of an external magnetic field. At low temperatures, and in the absence of an external magnetic field, our result show the spontaneous magnetization and the ferromagnetic phase transition. We find that the critical exponent takes the universal value beta = 1/2 regardless of the parameters q, z, d, which is in agreement with the mean field theory. In the presence of an external magnetic field, the magnetic susceptibility satisfies the Curie-Weiss law.

Automated summary

This study investigates the effects of Lifshitz dynamical exponent z on paramagnetic-ferromagnetic phase transition in Lifshitz spacetime, using numerical methods in the probe limit. Results show that critical temperature decreases with increasing power parameter q and dynamical exponent z, and the formation of magnetic moment is harder without an external magnetic field. The magnetic susceptibility satisfies the Curie-Weiss law in the presence of an external magnetic field.