Tobias J. Osborne, Michael A. Nielsen
Published 2001-09-05, updated 2002-04-02Version 2
We investigate the role of entanglement in quantum phase transitions, and show that the success of the density matrix renormalization group (DMRG) in understanding such phase transitions is due to the way it preserves entanglement under renormalization. We provide a reinterpretation of the DMRG in terms of the language and tools of quantum information science which allows us to rederive the DMRG in a physically transparent way. Motivated by our reinterpretation we suggest a modification of the DMRG which manifestly takes account of the entanglement in a quantum system. This modified renormalization scheme is shown,in certain special cases, to preserve more entanglement in a quantum system than traditional numerical renormalization methods.
Comments: 5 pages, 1 eps figure, revtex4; added reference and qualifying remarks
Journal: Quantum Information Processing, vol. 1 (1-2), pp. 45-53 (2002)
Quantum Phase Transitions and Matrix Product States in Spin Ladders
Entanglement Entropy and The Density Matrix Renormalization Group
Generalizations of entanglement based on coherent states and convex sets
