Convexity of momentum map, Morse index, and quantum entanglement

TL;DR

This paper explores the topological and geometric structure of quantum state classes under SLOCC operations, using momentum map geometry to classify entanglement and introduce new measures and algorithms for analysis.

Contribution

It introduces a geometric framework for classifying SLOCC classes, including an algorithm for critical set identification and a new entanglement measure based on total variance.

Findings

Classification of SLOCC classes into families using momentum map convexity

Algorithm for finding critical sets of total variance

Introduction of a SLOCC-invariant entanglement measure

Abstract

We analyze form the topological perspective the space of all SLOCC (Stochastic Local Operations with Classical Communication) classes of pure states for composite quantum systems. We do it for both distinguishable and indistinguishable particles. In general, the topology of this space is rather complicated as it is a non-Hausdorff space. Using geometric invariant theory (GIT) and momentum map geometry we propose a way to divide the space of all SLOCC classes into mathematically and physically meaningful families. Each family consists of possibly many `asymptotically' equivalent SLOCC classes. Moreover, each contains exactly one distinguished SLOCC class on which the total variance (a well defined measure of entanglement) of the state Var[v] attains maximum. We provide an algorithm for finding critical sets of Var[v], which makes use of the convexity of the momentum map and allows classification of such defined families of SLOCC classes. The number of families is in general infinite. We introduce an additional refinement into finitely many groups of families using the recent developments in the momentum map geometry known as Ness stratification. We also discuss how to define it equivalently using the convexity of the momentum map applied to SLOCC classes. Moreover, we note that the Morse index at the critical set of the total variance of state has an interpretation of number of non-SLOCC directions in which entanglement increases and calculate it for several exemplary systems. Finally, we introduce the SLOCC-invariant measure of entanglement as a square root of the total variance of state at the critical point and explain its geometric meaning.