Geometric quantification of multiparty entanglement through orthogonality of vectors

Abhinash Kumar Roy, Nitish Kumar Chandra, S Nibedita Swain, Prasanta K. Panigrahi

Published 2021-03-06Version 1

The wedge product of vectors has been shown (Quantum Inf. Process. 16(5): 118,2017) to yield the generalised entanglement measure I-concurrence, wherein the separability of the multiparty qubit system arises from the parallelism of vectors in the underlying Hilbert space of the subsystems. Here, we demonstrate that the orthogonality and equality of the post-measurement vectors maximize the entanglement corresponding to the bi-partitions and can yield non-identical set of maximally entangled states. The Bell states for the two qubit case, GHZ and GHZ like states with superposition of four constituents for three qubits, naturally arise as the maximally entangled states. Interestingly, the later two have identical I-concurrence but different entanglement distribution. While the GHZ states can teleport a single qubit deterministically, the second set achieves the same for a more general state. The geometric conditions for maximally entangled two qudit systems are derived, leading to the generalised Bell states, where the reduced density matrices are maximally mixed. We further show that the reduced density matrix for an arbitrary finite dimensional subsystem of a general qudit state can be constructed from the overlap of the post-measurement vectors. Our geometric approach shows the complimentary character of intrinsic coherence and entanglement.