Transport of quantum states and separation of ions in a dual RF ion trap
Quantum Information & Computation
Fabrication of micro-magnetic traps for cold neutral atoms
Quantum Information & Computation
Quantum Memory Hierarchies: Efficient Designs to Match Available Parallelism in Quantum Computing
Proceedings of the 33rd annual international symposium on Computer Architecture
Auxiliary qubit selection: a physical synthesis technique for quantum circuits
Quantum Information Processing
System design for large-scale ion trap quantum information processor
Quantum Information & Computation
Modeling ion trap thermal noise decoherence
Quantum Information & Computation
Demonstration of a scalable, multiplexed ion trap for quantum information processing
Quantum Information & Computation
A quantum physical design flow using ILP and graph drawing
Quantum Information Processing
Quantum circuit physical design methodology with emphasis on physical synthesis
Quantum Information Processing
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We investigate a surface-mounted electrode geometry for miniature linear radio frequencyPaul ion traps. The electrodes reside in a single plane on a substrate, and the pseudopotentialminimum of the trap is located above the substrate at a distance on the orderof the electrodes' lateral extent or separation. This architecture provides the possibilityto apply standard microfabrication principles to the construction of multiplexed iontraps, which may be of particular importance in light of recent proposals for large-scalequantum computation based on individual trapped ions.