Vlatko Vedral
Published 2007-01-15Version 1
I exploit the formal equivalence between the ground state of a $d$ dimensional quantum system and a d+1 dimensional classical Ising chain to represent quantum entanglement in terms of classical correlations only. This offers a general "local hidden variable model" for all quantum phenomena existing in one dimension lower than the (hidden variable) classical model itself. The local hidden variable model is not contradicted by the implications of Bell's theorem. Formal theory is presented first and then exemplified by the quantum Ising spin chain in a transverse magnetic field. Here I explicitely show how to derive any two site entanglement in the transverse model from the partition function of the classical Ising spin chain existing in two dimensions. Some speculations are then presented regarding possible fundamental implications of these results.
Comments: 6 pages, no figures, special issue of Journal of Modern Optics in honour of Peter Knight
The rise and fall of quantum and classical correlations in open-system dynamics
Dominance of quantum over classical correlations: entropic and geometric approach
Quantum and classical correlations in Bell three and four qubits, related to Hilbert-Schmidt decomposition
