Quantum transistor

Organization Name

Quantum Transistors Technology Ltd.

Inventor(s)

Igal Bayn of New York NY (US)

Moshe Tordjman of Haifa (IL)

Quantum transistor - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240281690 titled 'Quantum transistor

The abstract describes a quantum computing device that utilizes an optical resonator containing a crystalline material with a crystal defect. This defect has a ground state and an excited state with an emission wavelength within the resonant wavelength band. The device includes electrodes to apply electric fields to control the charge state of the crystal defect and tune the emission wavelength.

• Optical resonator with resonant wavelength band
• Crystalline material with crystal defect having ground and excited states
• Source and drain electrodes for applying electric field along longitudinal axis
• Gate electrode for applying electric field transverse to longitudinal axis
• Control circuitry to control charge state and emission wavelength tuning

Potential Applications: - Quantum computing - Optical signal processing - Quantum communication systems

Problems Solved: - Control of charge state in quantum computing devices - Precise tuning of emission wavelength

Benefits: - Enhanced control over quantum states - Improved efficiency in quantum computing operations

Commercial Applications: Title: Quantum Computing Device for Enhanced Emission Control This technology can be applied in industries such as: - Information technology - Telecommunications - Research and development

Prior Art: Readers can explore prior research on quantum computing devices, optical resonators, and crystal defects in quantum systems.

Frequently Updated Research: Stay updated on advancements in quantum computing technology, optical resonator design, and crystal defect manipulation techniques.

Questions about Quantum Computing Device for Enhanced Emission Control: 1. How does the crystal defect impact the emission wavelength in the quantum computing device? 2. What are the potential implications of precise emission wavelength tuning in quantum communication systems?

Original Abstract Submitted

a quantum computing device includes an optical resonator having a resonant wavelength band. a crystalline material including a crystal defect is contained within the optical resonator. the crystal defect has a ground state and an excited state, which has an emission wavelength in the resonant wavelength band. a source electrode and a drain electrode are disposed on opposing sides of the crystal defect and configured to apply a first electric field in the crystalline material along a longitudinal axis. a gate electrode is disposed in proximity to the crystal defect and configured to apply to the crystalline material a second electric field transverse to the longitudinal axis. control circuitry is configured to apply a first voltage between the source and drain electrodes to control a charge state of the crystal defect and to apply a second voltage to the gate electrode to tune the emission wavelength.