SUPERCONDUCTING QUANTUM INTERFEROMETRIC DEVICE AND MANUFACTURING METHOD

Organization Name

SAMSUNG ELECTRONICS CO., LTD.

Inventor(s)

Jaehyeong Lee of Suwon-si (KR)

Gilho Lee of Pohang-si (KR)

Jinhyoun Kang of Suwon-si (KR)

Jaeho Shin of Suwon-si (KR)

Seunghan Lee of Pohang-si (KR)

Daeseok Han of Suwon-si (KR)

SUPERCONDUCTING QUANTUM INTERFEROMETRIC DEVICE AND MANUFACTURING METHOD - A simplified explanation of the abstract

This abstract first appeared for US patent application 18194539 titled 'SUPERCONDUCTING QUANTUM INTERFEROMETRIC DEVICE AND MANUFACTURING METHOD

Simplified Explanation

The superconducting quantum interferometric device (SQUID) described in the patent application includes a first superconducting material layer with a first loop forming a proximity Josephson junction, a second superconducting material layer with a second loop, and a tunnel Josephson junction formed by a stack structure including a tunnel thin film layer and the first and second end units.

• Conductive material region on a substrate
• First superconducting material layer with a first loop and proximity Josephson junction
• Second superconducting material layer with a second loop
• Tunnel Josephson junction formed by a stack structure
• Second loop forming a stack structure with the first loop

Potential Applications

The technology described in the patent application could be used in:

• Quantum computing
• Magnetic field sensing
• High-sensitivity detectors

Problems Solved

This technology helps in:

• Enhancing sensitivity in detecting magnetic fields
• Improving quantum computing capabilities
• Enabling high-precision measurements

Benefits

The benefits of this technology include:

• High sensitivity
• Low noise interference
• Enhanced performance in quantum applications

Potential Commercial Applications

The potential commercial applications of this technology could be in:

• Medical imaging devices
• Magnetic resonance imaging (MRI) machines
• Scientific research equipment

Possible Prior Art

One possible prior art for this technology could be the development of superconducting quantum interference devices for magnetic field sensing in the field of quantum computing.

Unanswered Questions

How does this technology compare to traditional magnetic field sensors in terms of sensitivity and accuracy?

This question is not directly addressed in the article.

What are the potential challenges in scaling up this technology for commercial production?

The article does not provide information on the scalability challenges of this technology.

Original Abstract Submitted

A superconducting quantum interferometric device (SQUID) includes: a conductive material region formed on a partial region of a substrate; a first superconducting material layer including a first loop including first and second extension units that are spaced apart from each other to form a proximity Josephson junction and that form a stack structure with the conductive material region; a second superconducting material layer including a second loop including first and second end units spaced apart from each other; and a tunnel Josephson junction formed by a stack structure including a tunnel thin film layer forming and the first and second end units, wherein at least a portion of the second loop forms a stack structure with the first loop.