Demonstrates DC-voltage-controlled radial transport of a single ion through transition zones in a prototype ion trap chip for 2D quantum spring array architecture, with measurements of stray fields and heating rates.
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3 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 3representative citing papers
Micromotion enables high-fidelity fast entangling gates on radial modes of trapped-ion crystals with operation times of hundreds of nanoseconds.
A 3D-printed micro-ion trap with an enlarged loading zone improves hot-ion capture by keeping the Mathieu-q parameter low enough for effective laser cooling without lowering RF voltage.
citing papers explorer
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Demonstration of transport in an ion trap design for two-dimensional lattices
Demonstrates DC-voltage-controlled radial transport of a single ion through transition zones in a prototype ion trap chip for 2D quantum spring array architecture, with measurements of stray fields and heating rates.
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Radial Fast Entangling Gates Under Micromotion in Trapped-Ion Quantum Computers
Micromotion enables high-fidelity fast entangling gates on radial modes of trapped-ion crystals with operation times of hundreds of nanoseconds.
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Design and fabrication of a micro-ion trap with a 3D-printed loading zone for improved hot-ion capture
A 3D-printed micro-ion trap with an enlarged loading zone improves hot-ion capture by keeping the Mathieu-q parameter low enough for effective laser cooling without lowering RF voltage.