Bipartite entanglement and control in multiqubit systems

TL;DR

This paper investigates how control influences bipartite entanglement in multiqubit NMR systems using a geometric approach, providing solutions to the Schrödinger equation and analyzing entanglement dynamics through concurrence.

Contribution

It offers a geometric framework and analytical solutions for understanding control effects on entanglement in multiqubit systems, especially in NMR models with small couplings.

Findings

Control effects on entanglement appear at higher-order terms in time.

Solutions are expressed as power series in small parameters.

Certain controls can enhance or reduce bipartite entanglement.

Abstract

The effect of the control on bipartite entanglement is discussed from a geometric viewpoint for a nuclear magnetic resonance (NMR) system as a model of the n-qubit control system. The Hamiltonian of the model is the sum of the drift and control Hamiltonians, each of which describes the interaction between pairs of qubits and between one of qubits and an external magnetic field, respectively. According to a bipartite partition, the Schroedinger equation for the NMR system is put in the matrix form. This paper gives a solution to the Schroedinger equation with the assumptions of small coupling among qubits and of constant controls. The solution is put in the form of power series in small parameters. In particular, in the case of the two-qubit NMR system, the drift and control Hamiltonians are shown to be coupled to work for entanglement promotion, by examining solutions to the Schroedinger equation in detail. The concurrence, a measure of entanglement, is evaluated along the solution for a small time interval in order to observe that the control effect appears, not at the first-order terms in t, but at the higher-order terms in t. The evaluated concurrence also suggests which control makes the two-qubit more entangled or less.