A QUANTUM PROCESSING SYSTEM

Organization Name

Silicon Quantum Computing Pty Limited

Inventor(s)

Michelle Yvonne Simmons of New South Wales (AU)

Matthew Gregory House of New South Wales (AU)

Samuel Keith Gorman of New South Wales (AU)

Mark Richard Hogg of New South Wales (AU)

A QUANTUM PROCESSING SYSTEM - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240016069 titled 'A QUANTUM PROCESSING SYSTEM

Simplified Explanation

The present disclosure is about quantum processing systems that consist of multiple donor atom qubits placed in a semiconductor substrate. These systems also include control gates to manipulate the donor atom qubits. Additionally, there is an SLQD charge sensor fabricated on/in the semiconductor substrate, which is designed to detect the spin-states of two or more donor atom qubits within its sensing range.

• Quantum processing systems with donor atom qubits in a semiconductor substrate
• Control gates to control the donor atom qubits
• SLQD charge sensor on/in the semiconductor substrate
• SLQD charge sensor capable of sensing the spin-states of multiple donor atom qubits within its range

Potential applications of this technology:

• Quantum computing: The quantum processing systems described in the patent application can be used for quantum computing applications, which have the potential to solve complex problems more efficiently than classical computers.
• Quantum communication: The ability to control and sense the spin-states of donor atom qubits can be utilized for secure quantum communication protocols, such as quantum key distribution.
• Quantum sensing: The SLQD charge sensor can be employed for high-precision sensing applications, such as magnetic field detection or imaging.

Problems solved by this technology:

• Scalability: The use of donor atom qubits in a semiconductor substrate provides a potential solution for scaling up quantum processing systems, as it allows for the integration of multiple qubits on a single chip.
• Sensing limitations: The SLQD charge sensor addresses the challenge of detecting and measuring the spin-states of multiple donor atom qubits, which is crucial for quantum information processing.

Benefits of this technology:

• Enhanced quantum processing: The integration of donor atom qubits and the control gates in a semiconductor substrate can enable more efficient and reliable quantum processing.
• Improved sensing capabilities: The SLQD charge sensor offers high sensitivity and accuracy in detecting the spin-states of multiple donor atom qubits, enhancing the overall performance of quantum systems.
• Potential for practical applications: The scalability and sensing capabilities provided by this technology make it a promising candidate for various quantum technologies, including quantum computing, communication, and sensing.

Original Abstract Submitted

aspects of the present disclosure are directed to quantum processing systems that include a plurality of donor atom qubits positioned in a semiconductor substrate. the system also comprises a plurality of control gates configured to control the donor atom qubits. the system further comprises an slqd charge sensor fabricated on/in the semiconductor substrate. the slqd charge sensor is configured to sense spin-states of two or more donor atom qubits, which are positioned within a sensing range of the slqd charge sensor.