Simulation of Grover Search with Polar CH₃CN Molecules by Optimal Control Fields

Abstract: Theoretical schemes for the implementation of the Grover search algorithm are proposed based on ultracold polar molecules in an electric field. The molecular qubits and qudit are chosen as the field‐dressed states formed by the rotational modes of CH3CN. With the help of multi‐target optimal control theory, the microwave pulses for the elementary logic operations including the one‐qubit Hadamard gates and the conditional phase gates in a dipole‐dipole system are designed and the factorized Grover algorithm dem… Show more

“…Polar molecules have significant potential in the fields of quantum computation, − quantum simulation, − precision measurement, − and controlled chemistry − because they could provide the coherence times comparable to neutral atoms, strong controllable long-range interactions, and rich internal degrees of freedom. In 2002, DeMille originally proposed that the electric dipole moments of lattice-confined polar molecules, which are oriented along or against an external electric field, could serve as qubits in quantum information processing (QIP).…”

Entanglement Generation of Polar Molecules via Deep Reinforcement Learning

“…Polar molecules have significant potential in the fields of quantum computation, − quantum simulation, − precision measurement, − and controlled chemistry − because they could provide the coherence times comparable to neutral atoms, strong controllable long-range interactions, and rich internal degrees of freedom. In 2002, DeMille originally proposed that the electric dipole moments of lattice-confined polar molecules, which are oriented along or against an external electric field, could serve as qubits in quantum information processing (QIP).…”

Entanglement Generation of Polar Molecules via Deep Reinforcement Learning

Entropic uncertainty relation and entanglement of molecular dipoles in an electric field

Implementation of three-qubit Deutsch-Jozsa algorithm with pendular states of polar molecules by optimal control