Barenco gate implementation using driven two- and three-qubit spin chains

TL;DR

This paper presents an analytical protocol for implementing multi-qubit controlled gates, including CNOT and Toffoli, using driven spin chains with high fidelity and robustness, suitable for quantum information processing.

Contribution

The authors develop a fully analytical method to realize Barenco-type multi-qubit gates in spin chains, deriving explicit conditions and demonstrating high-fidelity implementation.

Findings

Achieves high operator fidelity in numerical simulations.

Provides explicit conditions for coupling and driving parameters.

Demonstrates robustness over broad parameter ranges.

Abstract

We propose a protocol for implementing Barenco-type multi-qubit controlled gates using short driven spin chains. Starting from an Ising interaction with a transverse drive on the last spin, we construct an effective two-qubit Hamiltonian whose time evolution implements the Barenco gate $V_2(\varphi,\omega,\phi)$ and, in particular, a CNOT gate. We then embed this construction into a three-qubit $XXZ$ chain to realize the three-qubit Barenco gate $V_3(\varphi,\omega,\phi)$, which includes the Toffoli gate as a special case. The derivation is fully analytical: we perform a sequence of unitary transformations, identify decoupled subspaces, and apply a rotating-wave approximation to obtain simple effective Hamiltonians. We derive explicit conditions on the coupling strengths and driving parameters, provide closed-form expressions for the time-evolution operators in each relevant subspace, and characterize the quality of the implementation using the operator fidelity. Numerical simulations show that the protocol achieves high fidelities over broad parameter ranges, demonstrating its robustness and suitability for quantum information processing in spin-chain platforms.