Wehrl Entropy and Entanglement Complexity of Quantum Spin Systems (2312.00611v2)

Abstract: The Wehrl entropy of a quantum state is the entropy of the coherent-state distribution function (Husimi function), and is non-zero even for pure states. We investigate the Wehrl entropy for $N$ spin-1/2 particles with respect to SU(2)$^{\otimes N}$ coherent states (i.e., the direct products of spin coherent states of each particle). We focus on: (1) The statistical interpretation of this Wehrl entropy. (2) The relationship between the Wehrl entropy and quantum entanglement. For (1), despite the coherent states not forming a group of orthonormal bases, we prove that the Wehrl entropy can still be interpreted as the entropy of a probability distribution with clear physical meaning. For (2), we numerically calculate the Wehrl entropy of various entangled pure states with particle number $2\leq N\leq 20$. Our results show that for the large-$N$ ($N\gtrsim 10$) systems the Wehrl entropy of the highly chaotic entangled states are much larger than that of the regular ones (e.g., the GHZ state). These results, together with the fact that the Wehrl entropy is invariant under local unitary transformations, indicate that the Wehrl entropy can reflect the complexity of the quantum entanglement (entanglement complexity) of many-body pure states, as A. Sugita proposed directly from the definitions of the Husimi function and Wehrl entropy (Jour. Phys. A 36, 9081 (2003)). Furthermore, the Wehrl entropy per particle can serve as a quantitative description of this complexity. We further show that the many-body pure entangled states can be classified into three types, according to the behaviors of the Wehrl entropy per particle in the limit $N\rightarrow\infty$, with the states of each type having very different entanglement complexity.