Quantum-brachistochrone approach to the conversion from $W$ to Greenberger-Horne-Zeilinger states for Rydberg-atom qubits

TL;DR

This paper employs the quantum-brachistochrone formalism to determine the fastest possible deterministic conversion between W and GHZ states in Rydberg-atom qubits, achieving significantly shorter conversion times than previous methods.

Contribution

It introduces a time-optimal control approach for W-to-GHZ state conversion in Rydberg-atom systems using quantum-brachistochrone equations, surpassing previous dynamical-symmetry-based times.

Findings

Shortest conversion time is 6.8ħ/E.

Time-optimal pulses are derived numerically.

Conversion time is significantly shorter than previous methods.

Abstract

Using the quantum-brachistochrone formalism, we address the problem of finding the fastest possible (time-optimal) deterministic conversion between $W$ and Greenberger-Horne-Zeilinger (GHZ) states in a system of three identical and equidistant neutral atoms that are acted upon by four external laser pulses. Assuming that all four pulses are close to being resonant with the same internal (atomic) transition -- the one between the atomic ground state and a high-lying Rydberg state -- each atom can be treated as an effective two-level system ($gr$-type qubit). Starting from an effective system Hamiltonian, which is valid in the Rydberg-blockade regime and defined on a four-state manifold, we derive the quantum-brachistochrone equations pertaining to the fastest possible $W$-to-GHZ state conversion. By numerically solving these equations, we determine the time-dependent Rabi frequencies of external laser pulses that correspond to the time-optimal state conversion. In particular, we show that the shortest possible $W$-to-GHZ state-conversion time is given by $T_{\textrm{QB}}= 6.8\:\hbar/E$, where $E$ is the total laser-pulse energy used, this last time being significantly shorter than the state-conversion times previously found using a dynamical-symmetry-based approach [$T_{\textrm{DS}}=(1.33-1.66)\:T_{\textrm{QB}}$].