L. Campos Venuti, C. Degli Esposti Boschi, G. Morandi, M. Roncaglia, A. Scaramucci
Published 2005-08-31, updated 2005-09-21Version 4
We discuss on general grounds some local indicators of entanglement, that have been proposed recently for the study and classification of quantum phase transitions. In particular, we focus on the capability of entanglement in detecting quantum critical points and related exponents. We show that the singularities observed in all local measures of entanglement are a consequence of the scaling hypothesis. In particular, as every non-trivial local observable is expected to be singular at criticality, we single out the most relevant one (in the renormalization group sense) as the best-suited for finite-size scaling analysis. The proposed method is checked on a couple of one-dimensional spin systems. The present analysis shows that the singular behaviour of local measures of entanglement is fully encompassed in the usual statistical mechanics framework.
Comments: 5 pages, 2 eps figures. Abstract replaced, minor changes in the text
Journal: Phys. Rev. A 73, 010303(R) (2006)
Entanglement, quantum phase transitions, and density matrix renormalization
Classical and Quantum Phase Transitions in Multiscale Media: Universality and Critical Exponents in the Fractional Ising Model
Quantum Phase Transitions and Matrix Product States in Spin Ladders
