David Lucas

Robust and fast microwave-driven quantum logic for trapped-ion qubits

(2024)

Authors:

MA Weber, MF Gely, RK Hanley, TP Harty, AD Leu, CM Löschnauer, DP Nadlinger, DM Lucas

Breaking the entangling gate speed limit for trapped-ion qubits using a phase-stable standing wave

Physical Review Letters American Physical Society 131:22 (2023) 220601

Authors:

Sebastian Saner, Oana Băzăvan, M Minder, Peter Drmota, DJ Webb, Gabriel Araneda Machuca, Raghavendra Srinivas, David M Lucas, Christopher J Ballance

Abstract:

All laser-driven entangling operations for trapped-ion qubits have hitherto been performed without control of the optical phase of the light field, which precludes independent tuning of the carrier and motional coupling. By placing ⁸⁸Sr⁺ ions in a λ=674  nm standing wave, whose relative position is controlled to ≈λ/100, we suppress the carrier coupling by a factor of 18, while coherently enhancing the spin-motion coupling. We experimentally demonstrate that the off-resonant carrier coupling imposes a speed limit for conventional traveling-wave Mølmer-Sørensen gates; we use the standing wave to surpass this limit and achieve a gate duration of 15  μs, restricted by the available laser power.

Cryogenic ion trap system for high-fidelity near-field microwave-driven quantum logic

Quantum Science and Technology IOP Publishing 9:1 (2023) 015007

Authors:

Marius Weber, Clemens Löschnauer, Jochen Wolf, Mario Gely, Ryan Hanley, Joseph Goodwin, Christopher Ballance, tom Harty, David Lucas

Abstract:

We report the design, fabrication, and characterization of a cryogenic ion trap system for the implementation of quantum logic driven by near-field microwaves. The trap incorporates an on-chip microwave resonator with an electrode geometry designed to null the microwave field component that couples directly to the qubit, while giving a large field gradient for driving entangling logic gates. We map the microwave field using a single 43Ca+ ion, and measure the ion trapping lifetime and motional mode heating rates for one and two ions.

In-situ characterization of qubit drive-phase distortions

(2023)

Authors:

MF Gely, JM Litarowicz, AD Leu, DM Lucas

Fast, High-Fidelity Addressed Single-Qubit Gates Using Efficient Composite Pulse Sequences.

Physical review letters 131:12 (2023) 120601

Authors:

AD Leu, MF Gely, MA Weber, MC Smith, DP Nadlinger, DM Lucas

Abstract:

We use electronic microwave control methods to implement addressed single-qubit gates with high speed and fidelity, for ^{43}Ca^{+} hyperfine "atomic clock" qubits in a cryogenic (100 K) surface trap. For a single qubit, we benchmark an error of 1.5×10^{-6} per Clifford gate (implemented using 600 ns π/2 pulses). For 2 qubits in the same trap zone (ion separation 5  μm), we use a spatial microwave field gradient, combined with an efficient four-pulse scheme, to implement independent addressed gates. Parallel randomized benchmarking on both qubits yields an average error 3.4×10^{-5} per addressed π/2 gate. The scheme scales theoretically to larger numbers of qubits in a single register.