Universal Barenco quantum gates via a tunable non-collinear interaction

Abstract

The Barenco gate~(B) is a type of two-qubit quantum gate based on which alone universal quantum computation can be achieved. Each B is characterized by three angles (α,θ, and φ) though it works in a two-qubit Hilbert space. Here we design B via a non-collinear interaction V|r1r2 r1r3|+H.c., where |ri is a state that can be excited from a qubit state and V is adjustable. We present two protocols of B. The first~(second) protocol consists of two~(six) pulses and one~(two) wait period(s), where the former causes rotations between the qubit states and excited states, and the latter induces gate transformation via the non-collinear interaction. In the first protocol, the variable φ can be tuned by varying phases of external controls, and the other two variables α and θ, tunable via adjusting the wait duration, have a linear dependence upon each other. Meanwhile, the first protocol can give rise to the CNOT and Controlled-Y gates. In the second protocol, α,θ, and φ can be varied by changing the interaction amplitudes and wait durations, and the latter two are dependent on α non-linearly. Both protocols can also lead to another universal gate when \α,φ\=\1/4,1/2\π with appropriate parameters. Implementation of these universal gates is analyzed based on the van der Waals interaction of neutral Rydberg atoms.