Dr Christopher Ballance

High-rate, high-fidelity entanglement of qubits across an elementary quantum network

(2019)

Authors:

LJ Stephenson, DP Nadlinger, BC Nichol, S An, P Drmota, TG Ballance, K Thirumalai, JF Goodwin, DM Lucas, CJ Ballance

Probing qubit memory errors at the part-per-million level

Physical Review Letters American Physical Society 123:11 (2019) 110503

Authors:

MA Sepiol, AC Hughes, JE Tarlton, DP Nadlinger, TG Ballance, CJ Ballance, TP Harty, AM Steane, JF Goodwin, David Lucas

Abstract:

Robust qubit memory is essential for quantum computing, both for near-term devices operating without error correction, and for the long-term goal of a fault-tolerant processor. We directly measure the memory error ε_m for a ⁴³Ca⁺ trapped-ion qubit in the small-error regime and find ε_m<10⁻⁴ for storage times t ≲ 50  ms. This exceeds gate or measurement times by three orders of magnitude. Using randomized benchmarking, at t = 1  ms we measure ε_m=1.2(7)×10⁻⁶, around ten times smaller than that extrapolated from the T^∗₂ time, and limited by instability of the atomic clock reference used to benchmark the qubit.

Probing Qubit Memory Errors at the Part-per-Million Level

(2019)

Authors:

MA Sepiol, AC Hughes, JE Tarlton, DP Nadlinger, TG Ballance, CJ Ballance, TP Harty, AM Steane, JF Goodwin, DM Lucas

Magnetic field stabilization system for atomic physics experiments

Review of Scientific Instruments AIP Publishing 90:4 (2019) 044702

Authors:

B Merkel, K Thirumalai, JE Tarlton, VM Schäfer, CJ Ballance, TP Harty, David Lucas

Abstract:

Atomic physics experiments commonly use millitesla-scale magnetic fields to provide a quantization axis. As atomic transition frequencies depend on the magnitude of this field, many experiments require a stable absolute field. Most setups use electromagnets, which require a power supply stability not usually met by commercially available units. We demonstrate the stabilization of a field of 14.6 mT to 4.3 nT rms noise (0.29 ppm), compared to noise of >100 nT without any stabilization. The rms noise is measured using a field-dependent hyperfine transition in a single 43Ca+ ion held in a Paul trap at the center of the magnetic field coils. For the 43Ca+ "atomic clock" qubit transition at 14.6 mT, which depends on the field only in second order, this would yield a projected coherence time of many hours. Our system consists of a feedback loop and a feedforward circuit that control the current through the field coils and could easily be adapted to other field amplitudes, making it suitable for other applications such as neutral atom traps.

Networking Trapped-ion Quantum Computers

Optica Publishing Group (2019) s2d.1

Authors:

CJ Ballance, LJ Stephenson, DP Nadlinger, BC Nichol, S An, JF Goodwin, P Drmota, DM Lucas