Spin and Magnetic Field Dependences of Quasiparticle Mass in Ferromagnetic State of Heavy Fermions

We investigate the mechanism underlying the suppression of heavy-fermion mass enhancement in the presence of a magnetic field. In the framework of statistically consistent Gutzwiller method (SGA) we study the periodic Anderson model in the strong correlation limit. The finite-U corrections are inclu...

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Published in:Journal of physics. Conference series 2012-01, Vol.391 (1), p.12022-4
Main Authors: Howczak, Olga, Spalek, Jozef
Format: Article
Language:English
Subjects:
Compensation
Correlation analysis
Electron spin
Electrons
Elementary excitations
Fermions
Ferromagnetic phases
Ferromagnetism
Magnetic fields
Magnetism
Mathematical models
Occupancy
Order disorder
Physics
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description We investigate the mechanism underlying the suppression of heavy-fermion mass enhancement in the presence of a magnetic field. In the framework of statistically consistent Gutzwiller method (SGA) we study the periodic Anderson model in the strong correlation limit. The finite-U corrections are included systematically allowing to describe the coexistence of Kondo compensation effect and ferromagnetic ordering, as well as weak delocalization of the f-electrons. In particular, we observe that the resulting mass enhancement factor of spin-up electrons and that of spin-down are not equal in ferromagnetic phases and depend strongly on the applied field and the f-level occupancy. We predict that mass enhancement for the spin-up quasiparticles is larger then that of spin-down and both of them decrease in the applied magnetic field. We argue that above features, as well as a nonmonotonic variation of the quasiparticle effective masses observed in our model are in good agreement with earlier experimental measurements for CexLa1−xB6.
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subjects Compensation
Correlation analysis
Electron spin
Electrons
Elementary excitations
Fermions
Ferromagnetic phases
Ferromagnetism
Magnetic fields
Magnetism
Mathematical models
Occupancy
Order disorder
Physics
title Spin and Magnetic Field Dependences of Quasiparticle Mass in Ferromagnetic State of Heavy Fermions
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