Bipartite representations and many-body entanglement of pure states of N indistinguishable particles

Abstract

We analyze a general bipartite-like representation of arbitrary pure states of N indistinguishable particles, valid for both bosons and fermions, based on M- and (N-M)-particle states. It leads to exact (M,N-M) Schmidt-like expansions of the state for any M<N and is directly related to the isospectral reduced M- and (N-M)-body density matrices (M) and (N-M). The formalism also allows for reduced yet still exact Schmidt-like decompositions associated with blocks of these densities, in systems having a fixed fraction of the particles in some single particle subspace. Monotonicity of the ensuing M-body entanglement under a certain set of quantum operations is also discussed. Illustrative examples in fermionic and bosonic systems with pairing correlations are provided, which show that in the presence of dominant eigenvalues in (M), approximations based on a few terms of the pertinent Schmidt expansion can provide a reliable description of the state. The associated one- and two-body entanglement spectrum and entropies are also analyzed.