Bose-Einstein condensation and entanglement in magnetic systems
Abstract
We present a study of magnetic field induced quantum phase transitions in insulating systems. A generalized scaling theory is used to obtain the temperature dependence of several physical quantities along the quantum critical trajectory (H=HC, T0) where H is a longitudinal external magnetic field and HC the critical value at which the transition occurs. We consider transitions from a spin liquid at a critical field HC1 and from a fully polarized paramagnet, at HC2, into phases with long range order in the transverse components. The transitions at HC1 and HC2 can be viewed as Bose-Einstein condensations of magnons which however belong to different universality classes since they have different values of the dynamic critical exponent z. Finally, we use that the magnetic susceptibility is an entanglement witness to discuss how this type of correlation sets in as the system approaches the quantum critical point along the critical trajectory, H=HC2, T0.
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