SILICON QUANTUM COMPUTING PTY LIMITED (20240349626). ADVANCED QUANTUM PROCESSING SYSTEMS AND METHODS FOR PERFORMING QUANTUM LOGIC OPERATIONS simplified abstract
Contents
- 1 ADVANCED QUANTUM PROCESSING SYSTEMS AND METHODS FOR PERFORMING QUANTUM LOGIC OPERATIONS
- 1.1 Organization Name
- 1.2 Inventor(s)
- 1.3 ADVANCED QUANTUM PROCESSING SYSTEMS AND METHODS FOR PERFORMING QUANTUM LOGIC OPERATIONS - A simplified explanation of the abstract
- 1.4 Simplified Explanation
- 1.5 Key Features and Innovation
- 1.6 Potential Applications
- 1.7 Problems Solved
- 1.8 Benefits
- 1.9 Commercial Applications
- 1.10 Prior Art
- 1.11 Frequently Updated Research
- 1.12 Questions about Quantum Processing Element
- 1.13 Original Abstract Submitted
ADVANCED QUANTUM PROCESSING SYSTEMS AND METHODS FOR PERFORMING QUANTUM LOGIC OPERATIONS
Organization Name
SILICON QUANTUM COMPUTING PTY LIMITED
Inventor(s)
Ludwik Kranz of Kensington, New South Wales (AU)
Samuel Keith Gorman of New South Wales (AU)
Md Serajum Monir of New South Wales (AU)
Stephen Roche of New South Wales (AU)
Daniel Keith of New South Wales (AU)
Rajib Rahman of New South Wales (AU)
Michelle Yvonne Simmons of New South Wales (AU)
ADVANCED QUANTUM PROCESSING SYSTEMS AND METHODS FOR PERFORMING QUANTUM LOGIC OPERATIONS - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240349626 titled 'ADVANCED QUANTUM PROCESSING SYSTEMS AND METHODS FOR PERFORMING QUANTUM LOGIC OPERATIONS
Simplified Explanation
The patent application discloses a quantum processing element and a method to perform logic operations on it. The element includes a semiconductor with dopant dots containing qubits, and the method involves controlling the spins of atoms and electrons to perform quantum logic operations.
- The quantum processing element consists of a semiconductor, a dielectric material, and dopant dots with qubits.
- Each dopant dot contains dopant atoms and confined electrons or holes, forming qubits based on spin.
- The method involves controlling nuclear spins and hyperfine interactions to perform quantum logic operations on qubits.
Key Features and Innovation
- Quantum processing element with dopant dots for qubits.
- Method to control spins and interactions for quantum logic operations.
- Integration of semiconductor technology with quantum computing principles.
Potential Applications
- Quantum computing
- Cryptography
- Data encryption
- Advanced simulations
- Machine learning
Problems Solved
- Enhancing quantum computing capabilities
- Improving data security
- Enabling complex calculations
- Advancing technology in various fields
Benefits
- Faster and more efficient computing
- Enhanced data protection
- Innovation in technology
- Potential for groundbreaking discoveries
Commercial Applications
Title: Quantum Processing Element for Advanced Computing This technology can be applied in industries such as:
- Information technology
- Cybersecurity
- Research and development
- Financial services
- Healthcare
Prior Art
Further research can be conducted in the field of quantum computing, semiconductor technology, and quantum logic operations to explore existing knowledge and developments.
Frequently Updated Research
Stay updated on advancements in quantum computing, semiconductor materials, and quantum information processing to understand the latest innovations and applications.
Questions about Quantum Processing Element
What are the potential real-world applications of quantum processing elements?
Quantum processing elements can be used in various industries for advanced computing, data encryption, simulations, and machine learning.
How does controlling spins and interactions in dopant dots contribute to quantum logic operations?
By controlling the spins of atoms and electrons in dopant dots, quantum logic operations can be performed efficiently and accurately.
Original Abstract Submitted
quantum processing element and method to perform logic operations on a quantum processing element are disclosed. the quantum processing element includes: a semiconductor, a dielectric material forming an interface with the semiconductor, a plurality of dopant dots embedded in the semiconductor, each of the dopant dots comprising one or more dopant atoms and one or more electrons or holes confined within the dopant dots, wherein spin of an unpaired electron or hole of each dopant dot forms at least one qubit. the method includes the step of: controlling orientation of nuclear spins of the one or more dopant atoms in a pair of dopant dots and/or controlling a hyperfine interaction between nuclear spins of one or more dopant atoms and electron or hole spins of the unpaired electron or hole in the pair of dopant dots to perform a quantum logic operation on a corresponding pair of qubits.
- SILICON QUANTUM COMPUTING PTY LIMITED
- Ludwik Kranz of Kensington, New South Wales (AU)
- Samuel Keith Gorman of New South Wales (AU)
- Md Serajum Monir of New South Wales (AU)
- Stephen Roche of New South Wales (AU)
- Daniel Keith of New South Wales (AU)
- Rajib Rahman of New South Wales (AU)
- Michelle Yvonne Simmons of New South Wales (AU)
- H10N60/10
- G06N10/40
- H03K17/92
- CPC H10N60/11