440 research outputs found
A short response-time atomic source for trapped ion experiments
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 , show we can
reach the desired level of flux in 12s, 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.Comment: 5 pages, 7 figure
Probing Qubit Memory Errors at the Part-per-Million Level
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 for
a Ca trapped-ion qubit in the small-error regime and find
for storage times t\lesssim50\,\mbox{ms}. This exceeds
gate or measurement times by three orders of magnitude. Using randomized
benchmarking, at t=1\,\mbox{ms} we measure ,
around ten times smaller than that extrapolated from the time,
and limited by instability of the atomic clock reference used to benchmark the
qubit.Comment: 8 pages, 5 figure
High-rate, high-fidelity entanglement of qubits across an elementary quantum network
We demonstrate remote entanglement of trapped-ion qubits via a
quantum-optical fiber link with fidelity and rate approaching those of local
operations. Two Sr qubits are entangled via the polarization
degree of freedom of two photons which are coupled by high-numerical-aperture
lenses into single-mode optical fibers and interfere on a beamsplitter. A novel
geometry allows high-efficiency photon collection while maintaining unit
fidelity for ion-photon entanglement. We generate remote Bell pairs with
fidelity at an average rate (success
probability ).Comment: v2 updated to include responses to reviewers, as published in PR
An optically-heated atomic source for compact ion trap vacuum systems
We present a design for an atomic oven suitable for loading ion traps, which
is operated via optical heating with a continuous-wave multimode diode laser.
The absence of the low-resistance electrical connections necessary for Joule
heating allows the oven to be extremely well thermally isolated from the rest
of the vacuum system, and for an oven filled with calcium we achieve a number
density suitable for rapid ion loading in the target region with ~200 mW of
laser power, limited by radiative losses. With simple feedforward to the laser
power, the turn-on time for the oven is less than 20 s, while the oven contains
enough calcium to operate continuously for many thousands of years without
replenishment.Comment: 7 pages, 5 figure
Multi-qubit gate with trapped ions for microwave and laser-based implementation
A proposal for a phase gate and a Mølmer–Sørensen gate in the dressed state basis is presented. In order to perform the multi-qubit interaction, a strong magnetic field gradient is required to couple the phonon-bus to the qubit states. The gate is performed using resonant microwave driving fields together with either a radio-frequency (RF) driving field, or additional detuned microwave driving fields. The gate is robust to ambient magnetic field fluctuations due to an applied resonant microwave driving field. Furthermore, the gate is robust to fluctuations in the microwave Rabi frequency and is decoupled from phonon dephasing due to a resonant RF or a detuned microwave driving field. This makes this new gate an attractive candidate for the implementation of high-fidelity microwave based multi-qubit gates. The proposal can also be realized in laser-based set-ups
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