Roland Matt scite author profile

We investigate theoretically the possibility for robust and fast cooling of a trapped atomic ion by transient interaction with a pre-cooled ion. The transient coupling is achieved through dynamical control of the ions’ equilibrium positions. To achieve short cooling times we make use of shortcuts to adiabaticity by applying invariant-based engineering. We design these to take account of imperfections such as stray fields, and trap frequency offsets. For settings appropriate to a currently operational trap in our laboratory, we find that robust performance could be achieved down to 6.3 motional cycles, comprising 14.2 μs for ions with a 0.44 MHz trap frequency. This is considerably faster than can be achieved using laser cooling in the weak coupling regime, which makes this an attractive scheme in the context of quantum computing.

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Industrially microfabricated ion trap with 1 eV trap depth

Auchter

Axline

Decaroli

et al. 2022

Quantum Sci. Technol.

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Scaling trapped-ion quantum computing will require robust trapping of at least hundreds of ions over long periods, while increasing the complexity and functionality of the trap itself. Symmetric three-dimensional (3D) structures enable high trap depth, but microfabrication techniques are generally better suited to planar structures that produce less ideal conditions for trapping. We present an ion trap fabricated on stacked 8-inch wafers in a large-scale micro-electro-mechanical system (MEMS) microfabrication process that provides reproducible traps at a large volume. Electrodes are patterned on the surfaces of two opposing wafers bonded to a spacer, forming a 3D structure with 2.5 µm standard deviation in alignment across the stack. We implement a design achieving a trap depth of 1 eV for a 40Ca+ ion held at 200 µm from either electrode plane. We characterize traps, achieving measurement agreement with simulations to within ±5% for mode frequencies spanning 0.6–3.8 MHz, and evaluate stray electric field across multiple trapping sites. We measure motional heating rates over an extensive range of trap frequencies, and temperatures, observing 40 phonons/s at 1 MHz and 185 K. This fabrication method provides a highly scalable approach for producing a new generation of 3D ion traps.

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Design, fabrication and characterization of a micro-fabricated stacked-wafer segmented ion trap with two X-junctions

Decaroli

Matt

Oswald

et al. 2021

Quantum Sci. Technol.

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We describe the implementation of a three-dimensional Paul ion trap fabricated from a stack of precision-machined silica glass wafers, which incorporates a pair of junctions for two-dimensional ion transport. The trap has 142 dedicated electrodes which can be used to define multiple potential wells in which strings of ions can be held. By supplying time-varying potentials, this also allows for transport and re-configuration of ion strings. We describe the design, simulation, fabrication and packaging of the trap, including explorations of different parameter regimes and possible optimizations and design choices. We give results of initial testing of the trap, including measurements of heating rates and junction transport.

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Multi-tone RF generation for parallel trapped-ion control

Stadler¹,

Nydegger²,

Matt³

et al. 2023

Preprint

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Optical Crosstalk Mitigation for Individual Addressing in a Cryogenic Ion Trap

Flannery

Matt

Huber

et al. 2022

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Roland Matt

Robust dynamical exchange cooling with trapped ions

Industrially microfabricated ion trap with 1 eV trap depth

Design, fabrication and characterization of a micro-fabricated stacked-wafer segmented ion trap with two X-junctions

Multi-tone RF generation for parallel trapped-ion control

Optical Crosstalk Mitigation for Individual Addressing in a Cryogenic Ion Trap

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