D. R. M. Pijn scite author profile

Moving trapped-ion qubits in a microstructured array of radiofrequency traps offers a route towards realizing scalable quantum processing nodes. Establishing such nodes, providing sufficient functionality to represent a building block for emerging quantum technologies, e.g. a quantum computer or quantum repeater, remains a formidable technological challenge. In this review, we present a holistic view on such an architecture, including the relevant components, their characterization and their impact on the overall system performance. We present a hardware architecture based on a uniform linear segmented multilayer trap, controlled by a custom-made fast multi-channel arbitrary waveform generator. The latter allows for conducting a set of different ion shuttling operations at sufficient speed and quality. We describe the relevant parameters and performance specifications for microstructured ion traps, waveform generators and additional circuitry, along with suitable measurement schemes to verify the system performance. Furthermore, a set of different basic shuttling operations for dynamic qubit register reconfiguration is described and characterized in detail.arXiv:1912.04712v1 [quant-ph]

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Magnetic-film atom chip with 10 μm period lattices of microtraps for quantum information science with Rydberg atoms

Leung

Pijn

Schlatter

et al. 2014

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We describe the fabrication and construction of a setup for creating lattices of magnetic microtraps for ultracold atoms on an atom chip. The lattice is defined by lithographic patterning of a permanent magnetic film. Patterned magnetic-film atom chips enable a large variety of trapping geometries over a wide range of length scales. We demonstrate an atom chip with a lattice constant of 10 μm, suitable for experiments in quantum information science employing the interaction between atoms in highly excited Rydberg energy levels. The active trapping region contains lattice regions with square and hexagonal symmetry, with the two regions joined at an interface. A structure of macroscopic wires, cutout of a silver foil, was mounted under the atom chip in order to load ultracold 87 Rb atoms into the microtraps. We demonstrate loading of atoms into the square and hexagonal lattice sections simultaneously and show resolved imaging of individual lattice sites. Magnetic-film lattices on atom chips provide a versatile platform for experiments with ultracold atoms, in particular for quantum information science and quantum simulation. © 2014 AIP Publishing LLC.

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Fault-Tolerant Parity Readout on a Shuttling-Based Trapped-Ion Quantum Computer

et al. 2022

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Fault-tolerant parity readout on a shuttling-based trapped-ion quantum computer

Hilder¹,

Pijn²,

Onishchenko³

et al. 2021

Preprint

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Shuttling-Based Trapped-Ion Quantum Information Processing

Kaushal¹,

Lekitsch²,

Stahl³

et al. 2019

Preprint

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D. R. M. Pijn

Shuttling-based trapped-ion quantum information processing

Magnetic-film atom chip with 10 μm period lattices of microtraps for quantum information science with Rydberg atoms

Fault-Tolerant Parity Readout on a Shuttling-Based Trapped-Ion Quantum Computer

Fault-tolerant parity readout on a shuttling-based trapped-ion quantum computer

Shuttling-Based Trapped-Ion Quantum Information Processing

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