Pairwise-parallel entangling gates on orthogonal modes in a trapped-ion chain

TL;DR

This paper introduces a parallel gate scheme on a trapped-ion quantum computer that uses orthogonal motional modes to double the effective gate depth, enhancing quantum computation efficiency without significant overhead.

Contribution

The authors propose and demonstrate a pairwise-parallel gate scheme on trapped ions, utilizing orthogonal motional modes to increase gate depth and efficiency.

Findings

Successfully created a GHZ state with parallel gates on a trapped-ion chain.

Extended the effective gate depth by up to two times without additional overhead.

Showed improved coherence and reduced heating effects using extra motional modes.

Abstract

Parallel operations are important for both near-term quantum computers and larger-scale fault-tolerant machines because they reduce execution time and qubit idling. We propose and implement a pairwise-parallel gate scheme on a trapped-ion quantum computer. The gates are driven simultaneously on different sets of orthogonal motional modes of a trapped-ion chain. We demonstrate the utility of this scheme by creating a GHZ state in one step using parallel gates with one overlapping qubit. We also show its advantage for circuits by implementing a digital quantum simulation of the dynamics of an interacting spin system, the transverse-field Ising model. This method effectively extends the available gate depth by up to two times with no overhead apart from additional initial cooling when no overlapping qubit is involved. This is because using a set of extra modes as additional quantum degrees of freedom is nearly equivalent to halving the trap heating rate, doubling the laser and qubit coherence time, and extending the controller memory depth by up to a factor of two. This scheme can be easily applied to different trapped-ion qubits and gate schemes, broadly enhancing the capabilities of trapped-ion quantum computers.