A High Motional Frequency Ion Trapping Regime for Quantum Information Science

TL;DR

This paper explores high motional frequency regimes in trapped ion systems to improve quantum information processing by reducing decoherence and increasing scalability.

Contribution

It proposes and investigates the high-frequency trapping regime, providing design strategies and analyzing its impact on cooling, coherence, and experimental efficiency.

Findings

High motional frequency traps can significantly reduce decoherence.

Design trajectories for high-frequency ion traps are identified.

Over an order-of-magnitude speedup in experimental duty cycles is achieved.

Abstract

We investigate high frequency motional states of trapped atomic ions. Trapped ions in rf traps are confined by an approximate harmonic potential and exhibit quantum motional states that mediate essential techniques in quantum computing, simulation, networking, and precision measurement. However, motional state decoherence mechanisms, heating and dephasing, are broadly limiting: reduced two-qubit gate fidelities; lower fidelity and lifetime of highly nonclassical bosonic states; long laser cooling times; and large recoil heating rates. These also challenge the scalability of increasingly sophisticated protocols. We propose high motional frequency ion trapping as an operating regime that addresses these challenges and reshapes the design landscape for quantum information experiments and quantum control techniques. We report an experimentally motivated investigation of realizing this high-frequency regime and discuss the consequences for laser cooling, motional state coherence, fidelity and lifetime of nonclassical bosonic states, and scalability of experimental runtimes. We report clear design trajectories for ion traps to reach high motional frequency, a new limiting mechanism for laser cooling at these high frequencies, and more than an order-of-magnitude speedup in experimental duty cycles with larger speed ups possible for quantum error correction protocols. Taken together, high motional frequency ion trapping has broad implications for the future of quantum information experiments.