Silicon microfabricated surface traps for trapped ion quantum information processing
Abstract not provided.
Publications
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Jump to search filtersIntegrated cavity QED in a linear ion trap for enhanced light collection
Abstract not provided.
Quantum information processing with trapped atoms
Abstract not provided.
Advanced ion trap structures with integrated tools for qubit manipulation
Abstract not provided.
Trapping ions in a segmented ring trap
Abstract not provided.
Micro-scale optics and optomechanics : from biomedical imaging to atomic physics
Abstract not provided.
Micro-device technologies for molecular ion physics and chemistry
Abstract not provided.
Design, fabrication and experimental demonstration of junction surface ion traps
New Journal of Physics
Abstract not provided.
Heating rate and electrode charging measurements in a scalable microfabricated surface-electrode ion trap
Applied Physics B
Abstract not provided.
Microfabricated surface ion traps with arbitrary lateral geometries
Abstract not provided.
Successful Integration of Fluorescence Collection Optics into a Microfabricated Surface Electrode Ion Trap
Applied Physics B
Abstract not provided.
Microfabricated surface ion traps for quantum computation
We will present results of the design, operation, and performance of surface ion micro-traps fabricated at Sandia. Recent progress in the testing of the micro-traps will be highlighted, including successful motional control of ions and the validation of simulations with experiments.
Ion trapping at Sandia : junction shuttling, cryogenic cooling, and laser development
Abstract not provided.
Sandia Ion Trap Foundry
Abstract not provided.
Engineering ion traps for quantum computing
Abstract not provided.
Ion trap layout
Abstract not provided.
Ion trap layout
Abstract not provided.
Fabrication and Applications of Ion Traps
Abstract not provided.
Demonstrating Robustness of Analogue Quantum Simulators (AQS)
In this report we describe the construction and characterization of a small quantum processor based on trapped ions. This processor could ultimately be used to perform analogue quantum simulations with an engineered computationally-cold bath for increasing the system's robustness to noise. We outline the requirements to build such a simulator, including individual addressing, distinguishable detection, and low crosstalk between operations, and our methods to implement and characterize these requirements. Specifically for measuring crosstalk, we introduce a new method, simultaneous gate set tomography to characterize crosstalk errors.
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