Quantum logic operations and creation of entanglement in a scalable superconducting quantum computer with long-range constant interaction between qubits

TL;DR

This paper explores quantum logic and entanglement creation in a scalable superconducting qubit chain with long-range constant interactions, demonstrating feasible implementation and error estimation for quantum algorithms.

Contribution

It introduces a method for entanglement creation in a long-range coupled superconducting qubit system without systematic errors, even with strong coupling.

Findings

Entanglement can be created with many qubits without systematic errors.

Large coupling constants increase the quantum computer's clock speed.

Errors due to long-range interactions are analytically estimated and numerically validated.

Abstract

We consider a one-dimensional chain of many superconducting quantum interference devices (SQUIDs), serving as charge qubits. Each SQUID is coupled to its nearest neighbors through constant capacitances. We study the quantum logic operations and implementation of entanglement in this system. Arrays with two and three qubits are considered in detail. We show that the creation of entanglement with an arbitrary number of qubits can be implemented, without systematic errors, even when the coupling between qubits is not small. A relatively large coupling constant allows one to increase the clock speed of the quantum computer. We analytically and numerically demonstrate the creation of the entanglement for this case, which can be a good test for the experimental implementation of a relatively simple quantum protocol with many qubits. We discuss a possible application of our approach for implementing universal quantum logic for more complex algorithms by decreasing the coupling constant and, correspondingly, decreasing the clock speed. The errors introduced by the long-range interaction for the universal logic gates are estimated analytically and calculated numerically. Our results can be useful for experimental implementation of quantum algorithms using controlled magnetic fluxes and gate voltages applied to the SQUIDs. The algorithms discussed in this paper can be implemented using already existing technologies in superconducting systems with constant inter-qubit coupling.