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Main Authors: Conta, Andreas, Bogino, Santiago, Köhncke, Frodo, Schmidt-Kaler, Ferdinand, Poschinger, Ulrich
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.08495
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author Conta, Andreas
Bogino, Santiago
Köhncke, Frodo
Schmidt-Kaler, Ferdinand
Poschinger, Ulrich
author_facet Conta, Andreas
Bogino, Santiago
Köhncke, Frodo
Schmidt-Kaler, Ferdinand
Poschinger, Ulrich
contents Scalable trapped-ion quantum computing requires fast and reliable transport of ions through complex, segmented radiofrequency trap architectures without inducing excessive motional excitation. We present a numerical toolchain for the systematic generation of time-dependent electrode voltages enabling fast, low-excitation ion shuttling in segmented radiofrequency traps. Based on a model of the trap electrode geometry, the framework combines an electrostatic field solver, efficient unconstrained optimization, waveform postprocessing, and dynamical simulations of ion motion to compute voltage waveforms that realize prescribed transport trajectories while respecting experimental constraints such as voltage limits and bandwidth. The toolchain supports arbitrary trap geometries, including junctions and multi-zone layouts, and allows for the flexible incorporation of optimization objectives. We provide a detailed assessment of the accuracy of the framework by investigating its numerical stability and by comparing measured and predicted secular frequencies. The framework is optimized for numerical performance, enabling rapid numerical prototyping of trap architectures of increasing complexity. As application examples, we apply the framework to the transport of a potential well along a linear, uniformly segmented trap, and we compute a solution for shuttling a potential well around the corner of an X-type trap junction. The presented approach provides an extensible and highly efficient numerical foundation for designing and validating transport protocols in current and next-generation trapped-ion processors.
format Preprint
id arxiv_https___arxiv_org_abs_2601_08495
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Toolchain for shuttling trapped-ion qubits in segmented traps
Conta, Andreas
Bogino, Santiago
Köhncke, Frodo
Schmidt-Kaler, Ferdinand
Poschinger, Ulrich
Quantum Physics
Scalable trapped-ion quantum computing requires fast and reliable transport of ions through complex, segmented radiofrequency trap architectures without inducing excessive motional excitation. We present a numerical toolchain for the systematic generation of time-dependent electrode voltages enabling fast, low-excitation ion shuttling in segmented radiofrequency traps. Based on a model of the trap electrode geometry, the framework combines an electrostatic field solver, efficient unconstrained optimization, waveform postprocessing, and dynamical simulations of ion motion to compute voltage waveforms that realize prescribed transport trajectories while respecting experimental constraints such as voltage limits and bandwidth. The toolchain supports arbitrary trap geometries, including junctions and multi-zone layouts, and allows for the flexible incorporation of optimization objectives. We provide a detailed assessment of the accuracy of the framework by investigating its numerical stability and by comparing measured and predicted secular frequencies. The framework is optimized for numerical performance, enabling rapid numerical prototyping of trap architectures of increasing complexity. As application examples, we apply the framework to the transport of a potential well along a linear, uniformly segmented trap, and we compute a solution for shuttling a potential well around the corner of an X-type trap junction. The presented approach provides an extensible and highly efficient numerical foundation for designing and validating transport protocols in current and next-generation trapped-ion processors.
title Toolchain for shuttling trapped-ion qubits in segmented traps
topic Quantum Physics
url https://arxiv.org/abs/2601.08495