Double-loop hysteresis of multisite dilute Sr(Y1-xDyx)2O4 single crystal Kramers paramagnets: electron-phonon interaction, quantum tunneling and cross-relaxation
Abstract
Experimental and theoretical studies of the dynamic magnetization in swept magnetic fields of the orthorhombic SrY2O4 single-crystals doped with the Dy3+ Kramers ions (0.01 and 0.5 at.%) with natural abundances of even and odd Dy isotopes are presented. Impurity ions substitute for Y3+ ions at two nonequivalent crystallographic sites with the same local Cs symmetry but strongly different crystal fields. Well pronounced double-loop hysteresis is observed at temperatures 2, 4, 5 and 6 K for sweeping rates of 5 and 1 mT/s. The microscopic model of spectral, magnetic and kinetic properties of Dy3+ ions is developed based on the results of EPR, site selective optical spectra and magnetic relaxation measurements. The derived approach to the dynamic magnetization in the sweeping field based on the numerical solution of generalized master equations with time-dependent transition probabilities induced by the electron-phonon interaction, quantum tunneling and cross-relaxation allowed us to reproduce successfully the evolution of the hysteresis loop shape with temperature, sweeping rate and concentration of paramagnetic ions.
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