Polylogarithmic-depth controlled-NOT gates without ancilla qubits

Abstract

Controlled operations are fundamental building blocks of quantum algorithms. Decomposing n-control-NOT gates (Cn(X)) into arbitrary single-qubit and CNOT gates, is a crucial but non-trivial task. This study introduces Cn(X) circuits outperforming previous methods in the asymptotic and non-asymptotic regimes. Three distinct decompositions are presented: an exact one using one borrowed ancilla with a circuit depth ((n)3), an approximating one without ancilla qubits with a circuit depth O ((n)3(1/ε)) and an exact one with an adjustable-depth circuit which decreases with the number m≤ n of ancilla qubits available as O(log(2n/m)3+log(m/2)). The resulting exponential speedup is likely to have a substantial impact on fault-tolerant quantum computing by improving the complexities of countless quantum algorithms with applications ranging from quantum chemistry to physics, finance and quantum machine learning.

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