Optimization and implementation of a surface-electrode ion trap junction

• URL: http://arxiv.org/abs/2201.12579v1
• Date: Sat, 29 Jan 2022 12:47:39 GMT
• Title: Optimization and implementation of a surface-electrode ion trap junction
• Authors: Chi Zhang, Karan K Mehta and Jonathan P Home
• Abstract summary: We describe the design of a surface-electrode ion trap junction, which is a key element for large-scale ion trap arrays. A bi-objective optimization method is used for designing the electrodes, which maintains the total pseudo-potential curvature. integrated optical addressing contributes to modular trapped-ion quantum computing in interconnected 2-dimensional arrays.
• Score: 6.285167805465505
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: We describe the design of a surface-electrode ion trap junction, which is a key element for large-scale ion trap arrays. A bi-objective optimization method is used for designing the electrodes, which maintains the total pseudo-potential curvature while minimizing the axial pseudo-potential gradient along the ion transport path. To facilitate the laser beam delivery for parallel operations in multiple trap zones, we implemented integrated optics on each arm of this X-junction trap. The layout of the trap chip for commercial foundry fabrication is presented. This work suggests routes to improving ion trap junction performance in scalable implementations. Together with integrated optical addressing, this contributes to modular trapped-ion quantum computing in interconnected 2-dimensional arrays.

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