Plasma quantum computer
By representing binary states with positive and negative electron charges in neutron plasma, quantum computers achieve stability and ultra-parallel processing, overcoming stability and reliability challenges.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- パテントフレア株式会社
- Filing Date
- 2024-12-26
- Publication Date
- 2026-07-08
AI Technical Summary
Quantum computers face challenges in stability and reliability during calculations due to existing methods of representing binary states with electrons, limiting their practical application.
Representing binary states using positive and negative charges of electrons within neutron plasma, enabling ultra-parallel processing by utilizing plasma-enhanced neutron plasma and electrostatic control technologies.
Stabilizes quantum computer calculations and enables ultra-parallel processing, addressing stability and reliability issues.
Abstract
Description
Technical Field
[0001] The present invention relates to an applied technology of computer technology, plasma technology, and electrostatic control technology.
Background Art
[0002] The technology of thermal guns (plasma guns)
[0003] The electrostatic control technology in clean rooms, etc.
Summary of the Invention
Problems to be Solved by the Invention
[0004] A quantum computer is considered to be able to solve complex problems that take an enormous amount of time to calculate with an ordinary computer by ultra-parallel processing in a relatively short time. Although various methods have been studied, it has not been put into practical use due to problems such as stability during calculation and reliability of results. Therefore, a method different from the methods studied so far is proposed.
Means for Solving the Problems
[0005] Most of the quantum computers studied so far have been a method of calculating by representing binary 0 and 1 with the on and off of electrons. However, by applying the electrostatic control technology, a method of representing binary 0 and 1 with positive charges (positive electrons) and negative charges (negative electrons) of electrons is adopted. Furthermore, calculations are performed using neutron plasma in which electrons are made into plasma. Neutron plasma is an electron that has the physical property of being able to become either a positive charge (positive electron) or a negative charge (negative electron). Therefore, all electrons used in the calculation can become either 0 or 1. This state corresponds to the state of superposition in quantum mechanics (being both 0 and 1), so that ultra-parallel calculation (processing) becomes possible. Instead of the many quantum computer methods studied so far, which divide electrons into two states, on (lit) and off (off), and assign the difference between states to binary 0 and 1, this method divides electrons into two states, positively charged (positive electrons) and negatively charged (negative electrons), and assigns the difference between states to binary 0 and 1. The electrons used for calculations are plasma-enhanced neutron plasma. Because neutron plasma can be in either a positively charged (positive electrons) or negatively charged (negative electrons) state, it enables parallel processing that allows multiple calculations to be performed simultaneously. Furthermore, plasma manufacturing and utilization technologies, as well as electrostatic control technologies, are used in various fields and are therefore technically established, ensuring stability even when applied to quantum computers. This method can be used to control quantum computers and solve the problem.
Claims
1. A quantum computer is a computer that applies the principles of quantum mechanics to computation. This technology aims to solve problems that are too complex for conventional computers, utilizing the laws of quantum mechanics. It is believed to enable ultra-parallel processing impossible with conventional electronic circuits by leveraging superpositions of states and quantum entanglement observed in the extremely small world of microscopic physical phenomena such as molecules, atoms, and electrons. Currently, various methods for realizing quantum computers have been proposed, but the five most promising are the superconducting method, the silicon method, the optical method, the ion trap method, and the cold atom method. All of these technologies have issues such as stability and have not yet reached practical application. Previously, 0 and 1 in binary were represented by the on and off states of electrons, but this will be changed to a method that uses positive charge (positive electrons) and negative load (negative electrons) by applying electrostatic control technology. Based on this fundamental method, calculations are performed using neutron plasma, which is created by encapsulating electrons in a plasma state. Because a neutron plasma can be in either a positive charge (positive electrons) or a negative load (negative electrons) state, this corresponds to the superposition state in quantum mechanics (being both 0 and 1). Since all the electrons (neutron plasma) used in the calculation are both 0 and 1 (they can be either 0 or 1), ultra-parallel processing is possible. Furthermore, plasma manufacturing technology and electrostatic control technology are established technologies used in various fields, ensuring stability. This is a quantum computer control method that uses neutron plasma to perform calculations using a system where the positive charge (positive electrons) and negative load (negative electrons) of electrons represent 0 and 1 in binary. Unlike previous quantum computer methods that represent binary 0s and 1s by switching electrons on and off and attempt to reproduce phenomena observed in quantum mechanics by making electron movement (current flow) smoother, or by using Majorana particles to make one electron represent both binary 0s and 1s, this method focuses on the properties of electrons themselves, classifying them into positively charged (positive electrons) and negatively charged (negative electrons), representing the difference between binary 0s and 1s, and using electrons that can be either one or the other (neutron plasma), thereby reproducing phenomena such as superposition and quantum entanglement (being both 0 and 1, and not knowing which state it is until it is checked) observed in the world of quantum mechanics, and is used as the control method for quantum computers.
2. Quantum computer using the method described in claim 1
3. OS for controlling the quantum computer described in claim 2
4. Services and businesses using the quantum computer described in claim 2.