The density matrix recursion method: genuine multisite entanglement distinguishes odd from even quantum spin ladder states

Cite

Related Material

Institute of Physics (IOP)

Deutsche Physikalische Gesellschaft (DPG)

Dhar, Himadri Shekhar Sen(De), Aditi Sen, Ujjwal

Formal Metadata

Title

The density matrix recursion method: genuine multisite entanglement distinguishes odd from even quantum spin ladder states

Title of Series

New Journal of Physics, Volume 15, 2013

Number of Parts

Author

Dhar, Himadri Shekhar

Sen(De), Aditi

Sen, Ujjwal

License

CC Attribution 3.0 Unported:
You are free to use, adapt and copy, distribute and transmit the work or content in adapted or unchanged form for any legal purpose as long as the work is attributed to the author in the manner specified by the author or licensor.

Identifiers

10.5446/39049 (DOI)

Publisher

Institute of Physics (IOP)

Deutsche Physikalische Gesellschaft (DPG)

Release Date

2013

Language

English

Content Metadata

Subject Area

Physics

Genre

Video Abstract

Abstract

We introduce an analytical iterative method, the density matrix recursion method, to generate arbitrary reduced density matrices of superpositions of short-range dimer coverings on periodic or non-periodic quantum spin-1/2 ladder lattices, with an arbitrary number of legs. The method can be used to calculate bipartite as well as multipartite physical properties, including bipartite and multi-partite entanglement. We apply this technique to distinguish between even- and odd-legged ladders. Specifically, we show that while genuine multi-partite entanglement decreases with increasing system size for the even-legged ladder states, it does the opposite for odd-legged ones.