UCHICAGO ARGONNE, LLC (20240304353). NOBLE GAS SOLID-STATE SINGLE ELECTRON QUBIT PLATFORM simplified abstract
NOBLE GAS SOLID-STATE SINGLE ELECTRON QUBIT PLATFORM
Organization Name
Inventor(s)
Xianjing Zhou of Westmont IL (US)
Gerwin Koolstra of Chicago IL (US)
David I. Schuster of Chicago IL (US)
NOBLE GAS SOLID-STATE SINGLE ELECTRON QUBIT PLATFORM - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240304353 titled 'NOBLE GAS SOLID-STATE SINGLE ELECTRON QUBIT PLATFORM
The patent application describes a qubit platform device designed for quantum computing systems, featuring long coherence, scalability, and fast operation.
- The device includes a substrate with solid neon, a trap region, and a trap electrode creating a confining electrical field.
- First and second sets of guard electrodes allow for trapping and manipulation of a single electron in the confining region.
Potential Applications: This technology could revolutionize quantum computing by enabling faster and more efficient qubit operations.
Problems Solved: The device addresses the need for qubit devices with long coherence, scalability, and fast operation in quantum computing systems.
Benefits: Improved performance and efficiency in quantum computing systems, leading to advancements in various fields such as cryptography, optimization, and simulation.
Commercial Applications: This technology could be applied in industries requiring complex computational tasks, such as finance, healthcare, and materials science.
Prior Art: Researchers interested in this technology should explore patents related to qubit devices, trap electrodes, and quantum computing systems.
Frequently Updated Research: Stay informed about the latest developments in qubit devices, trap electrodes, and quantum computing systems to understand the evolving landscape of this technology.
Questions about Qubit Platform Devices: 1. How does the use of solid neon in the substrate enhance the performance of the qubit platform device? 2. What are the implications of the confining electrical field created by the trap electrode on the manipulation of electrons in the device?
Original Abstract Submitted
qubit devices require fast operation, long coherence, and large scalability to be viable for implementation in quantum computing systems. a qubit platform device having long coherence, scalability, and fast operation includes a substrate, or trap region, configured to structurally support solid neon thereon. a trap electrode is configured to provide a trap voltage to the trap region and which creates a confining electrical field to a confining region adjacent to the trap region. the confining region being a region of space to confine an electron therein, confining the electron against the solid neon. first and second sets of guard electrodes are configured to provide variable electric potentials to first and second guard regions to allow for trapping and manipulation of a single electron in the confining region.
