Topological entropy in physics

For the mathematical concept in ergodic theory, see topological entropy.

The topological entanglement entropy^{[1] [2]} or topological entropy, usually denoted by γ, is a number characterizing many-body states that possess topological order.

A non-zero topological entanglement entropy reflects the presence of long range quantum entanglements in a many-body quantum state. So the topological entanglement entropy links topological order with pattern of long range quantum entanglements.

Given a topologically ordered state, the topological entropy can be extracted from the asymptotic behavior of the Von Neumann entropy measuring the quantum entanglement between a spatial block and the rest of the system. The entanglement entropy of a simply connected region of boundary length L, within an infinite two-dimensional topologically ordered state, has the following form for large L:

${\displaystyle S_{L}\;\longrightarrow \;\alpha L-\gamma +{\mathcal {O}}(L^{-\nu })\;,\qquad \nu >0\,\!}$

-γ is the topological entanglement entropy.

The topological entanglement entropy is equal to the logarithm of the total quantum dimension of the quasiparticle excitations of the state.

For example, the simplest fractional quantum Hall states, the Laughlin states at filling fraction 1/m, have γ = ½log(m). The Z₂ fractionalized states, such as topologically ordered states of Z₂ spin-liquid, quantum dimer models on non-bipartite lattices, and Kitaev's toric code state, are characterized γ = log(2).

See also

• Quantum topology
• Topological defect
• Topological order
• Topological quantum field theory
• Topological quantum number
• Topological string theory

References

Introduction of the measure

1. ^ Topological Entanglement Entropy, Alexei Kitaev and John Preskill, Phys. Rev. Lett. 96, 110404 (2006).
2. ^ Detecting Topological Order in a Ground State Wave Function, Michael Levin and Xiao-Gang Wen, Phys. Rev. Lett. 96, 110405 (2006).

Calculations for specific topologically ordered states

• M. Haque, O. Zozulya and K. Schoutens; Phys. Rev. Lett. 98, 060401 (2007).
• S. Furukawa and G. Misguich, Phys. Rev. B 75, 214407 (2007).