Dr Christopher Ballance

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

Magnetic field stabilization system for atomic physics experiments

(2018)

Authors:

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

A short response-time atomic source for trapped ion experiments

Review of Scientific Instruments AIP Publishing 89:5 (2018) 053102

Authors:

Timothy G Ballance, Joseph Goodwin, B Nichol, LJ Stephenson, CJ Ballance, DM Lucas

Abstract:

Ion traps are often loaded from atomic beams produced by resistively heated ovens. We demonstrate an atomic oven which has been designed for fast control of the atomic flux density and reproducible construction. We study the limiting time constants of the system and, in tests with 40Ca, show we can reach the desired level of flux in 12 s, with no overshoot. Our results indicate that it may be possible to achieve an even faster response by applying an appropriate one-off heat treatment to the oven before it is used.

Fast quantum logic gates with trapped-ion qubits

Nature Nature Publishing Group 555:7694 (2018) 75-78

Authors:

VM Schäfer, Christopher Ballance, K Thirumalai, LJ Stephenson, TG Ballance, AM Steane, David Lucas

Abstract:

Quantum bits (qubits) based on individual trapped atomic ions are a promising technology for building a quantum computer. The elementary operations necessary to do so have been achieved with the required precision for some error-correction schemes. However, the essential two-qubit logic gate that is used to generate quantum entanglement has hitherto always been performed in an adiabatic regime (in which the gate is slow compared with the characteristic motional frequencies of the ions in the trap), resulting in logic speeds of the order of 10 kilohertz. There have been numerous proposals of methods for performing gates faster than this natural 'speed limit' of the trap. Here we implement one such method, which uses amplitude-shaped laser pulses to drive the motion of the ions along trajectories designed so that the gate operation is insensitive to the optical phase of the pulses. This enables fast (megahertz-rate) quantum logic that is robust to fluctuations in the optical phase, which would otherwise be an important source of experimental error. We demonstrate entanglement generation for gate times as short as 480 nanoseconds-less than a single oscillation period of an ion in the trap and eight orders of magnitude shorter than the memory coherence time measured in similar calcium-43 hyperfine qubits. The power of the method is most evident at intermediate timescales, at which it yields a gate error more than ten times lower than can be attained using conventional techniques; for example, we achieve a 1.6-microsecond-duration gate with a fidelity of 99.8 per cent. Faster and higher-fidelity gates are possible at the cost of greater laser intensity. The method requires only a single amplitude-shaped pulse and one pair of beams derived from a continuous-wave laser. It offers the prospect of combining the unrivalled coherence properties, operation fidelities and optical connectivity of trapped-ion qubits with the submicrosecond logic speeds that are usually associated with solid-state devices.