nLab entanglement entropy

Redirected from "topological entanglement entropy".
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Quantum systems

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quantum probability theoryobservables and states


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Measure and probability theory

Contents

Idea

entropy induced by entanglement in quantum physics, essentially a synonym for subsystem entropy.

If ρ\rho is a quantum state (density matrix) of some quantum systems and AA is a subsystem with complementary subsystem A¯\overline{A}, then its entanglement entropy is

S ATr A(ρ Alnρ A),whereρ ATr A¯(ρ). S_A \;\coloneqq\; - Tr_{A}\big( \rho_A \ln \rho_A \big) \,, \;\;\; \text{where} \;\;\; \rho_A \;\coloneqq\; Tr_{\bar A}(\rho) \,.

Special aspects:

A constant contribution to S AS_A (i.e. independent of the choice of AA, in a suitable sense) is called a topological entanglement entropy indicating long-range entanglement and “topological order”, being proportional to the total quantum dimension of anyon-excitations. (See the references below.)

On the other extreme, for short range entanglement the entanglement entropy is thought to scale with the surface area of the subsystem AA (to the extent that this makes sense, say in say in lattice models), a behaviour reminiscent of Bekenstein-Hawking entropy of black holes. For more on this see at holographic entanglement entropy.

quantum probability theoryobservables and states

References

General

  • Matthew Headrick, Lectures on entanglement entropy in field theory and holography (arXiv:1907.08126)

In AQFT:

See also

Topological entanglement entropy

On entanglement entropy in arithmetic Chern-Simons theory:

  • Hee-Joong Chung, Dohyeong Kim, Minhyong Kim, Jeehoon Park, Hwajong Yoo, Entanglement entropies in the abelian arithmetic Chern-Simons theory [arXiv:2312.17138]

General

Identification of a contribution to entanglement entropy at absolute zero which is independent of the subsystem‘s size (“topological entanglement entropy”, “long-range entanglement”), reflecting topological order and proportional to the total quantum dimension of anyon excitations:

Review:

In terms of Renyi entropy (it’s independent of the Renyi entropy parameter):

  • Ulrich Schollwöck, (Almost) 25 Years of DMRG - What Is It About? (pdf)

and in the example of Chern-Simons theory:

Discussion in the dimer model:

  • Shunsuke Furukawa, Gregoire Misguich, Topological Entanglement Entropy in the Quantum Dimer Model on the Triangular Lattice, Phys. Rev. B 75, 214407 (2007) (arXiv:cond-mat/0612227)

Discussion via holographic entanglement entropy:

  • Ari Pakman, Andrei Parnachev, Topological Entanglement Entropy and Holography, JHEP 0807: 097 (2008) (arXiv:0805.1891)

  • Andrei Parnachev, Napat Poovuttikul, Topological Entanglement Entropy, Ground State Degeneracy and Holography, Journal of High Energy Physics volume 2015, Article number: 92 (2015) (arXiv:1504.08244)

See also:

  • Tatsuma Nishioka, Tadashi Takayanagi, Yusuke Taki, Topological pseudo entropy (arXiv:2107.01797)

Relation to strong interaction

Relation of long-range entanglement to strong interaction:

  • Jan Zaanen, Yan Liu, Ya-Wen Sun, Koenraad Schalm, Holographic Duality in Condensed Matter Physics, Cambridge University Press 2015 [[doi:10.1017/CBO9781139942492]]

    In a way it appears obvious that the strongly interacting bosonic quantum critical state is subject to long-range entanglement. Nonetheless, the status of this claim is conjectural.

    It is at present impossible to arrive at more solid conclusions that are based on rigorous mathematical procedures. It does illustrate emphatically the central challenge in the pursuit of field-theoretical quantum information: there are as yet not general measures available to precisely enumerate the meaning of long-range entanglement in such seriously quantum field-theoretical systems. [[p. 527]]

  • Tsung-Cheng Lu, Sagar Vijay, Characterizing Long-Range Entanglement in a Mixed State Through an Emergent Order on the Entangling Surface [[arXiv:2201.07792]]

    strongly interacting quantum phases of matter at zero temperature can exhibit universal patterns of long-range entanglement

Characterizing topological order

On characterizing anyon braiding / modular transformations on topologically ordered ground states by analysis of (topological) entanglement entropy of subregions:

Simulation and experiment

Experimental observation:

Detection of long-range entanglement entropy in quantum simulations on quantum computers:

exposition in:

Last revised on May 26, 2022 at 10:12:35. See the history of this page for a list of all contributions to it.