18571165. QUANTUM STATE STABILIZATION BY QUANTUM COUPLING simplified abstract (The Regents of the University of California)

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QUANTUM STATE STABILIZATION BY QUANTUM COUPLING

Organization Name

The Regents of the University of California

Inventor(s)

Michael Scheibner of Merced CA (US)

Mark Woodall of Merced CA (US)

QUANTUM STATE STABILIZATION BY QUANTUM COUPLING - A simplified explanation of the abstract

This abstract first appeared for US patent application 18571165 titled 'QUANTUM STATE STABILIZATION BY QUANTUM COUPLING

The patent application discusses techniques, systems, and apparatuses designed to reduce susceptibility to charge noise in a device.

  • Electrical contacts are included in the device.
  • An atom-like system interacts with a first electrical field provided through the electrical contacts and produces a second electrical field in response.
  • Another atom-like structure interacts with both the first and second electrical fields, making it less sensitive to charge noise.

Potential Applications: - Electronic devices requiring high sensitivity and low susceptibility to charge noise. - Quantum computing systems. - Sensors for precise measurements.

Problems Solved: - Minimizing interference from charge noise in sensitive electronic systems. - Enhancing the reliability and accuracy of measurements in quantum computing.

Benefits: - Improved performance and accuracy in electronic devices. - Enhanced stability and reliability in quantum computing systems. - Reduction in errors and inaccuracies due to charge noise interference.

Commercial Applications: Title: "Enhancing Sensitivity and Stability in Electronic Devices" This technology can be applied in industries such as telecommunications, healthcare, and scientific research where precise measurements and low noise interference are crucial.

Questions about the technology: 1. How does this technology compare to existing methods for reducing charge noise in electronic devices? 2. What are the potential limitations or challenges in implementing this technology in practical applications?


Original Abstract Submitted

Generally discussed herein are techniques for and systems and apparatuses configured to reduce susceptibility to charge noise. A device can include electrical contacts, an atom-like system situated to interact with a first electrical field provided through the electrical contacts and produce a second electrical field responsive to the first electrical field, and an atom-like structure situated to interact with the first electrical field and the second electrical field, such that the atom-like structure is less sensitive to charge noise in the device.