METAL DOPED ORGANIC FRAMEWORK-BASED CATALYST, AND OXYGEN SENSING ELECTRODE USING SAME

Organization Name

PUSAN NATIONAL UNIVERSITY INDUSTRY-UNIVERSITY COOPERATION FOUNDATION

Inventor(s)

Yoon-Bo Shim of Busan (KR)

Deog Su Park of Busan (KR)

Sang Kon Lee of Busan (KR)

Jae Hoon Lee of Ulsan (KR)

Sang Hoon Kim of Anyang-si (KR)

METAL DOPED ORGANIC FRAMEWORK-BASED CATALYST, AND OXYGEN SENSING ELECTRODE USING SAME - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240011936 titled 'METAL DOPED ORGANIC FRAMEWORK-BASED CATALYST, AND OXYGEN SENSING ELECTRODE USING SAME

Simplified Explanation

The present invention is a metal-doped organic framework-based catalyst and an oxygen sensing electrode that uses this catalyst. The 3D oxygen sensing electrode can be easily and quickly manufactured at a low cost by using a trace amount of noble metal. This is achieved through a polymer/graphene/nanocatalyst composition prepared by 3D printing and nanocatalyst synthesis based on a metal-doped organic framework. The electrode is capable of selectively sensing gases and dissolved oxygen and exhibits long-term stability.

• The invention is a metal-doped organic framework-based catalyst and an oxygen sensing electrode.
• The electrode is manufactured easily and quickly at a low cost.
• A trace amount of noble metal is used in the electrode.
• The composition used in the electrode is prepared by 3D printing and nanocatalyst synthesis.
• The electrode can selectively sense gases and dissolved oxygen.
• The electrode exhibits long-term stability.

Potential Applications

This technology can have various potential applications, including:

• Environmental monitoring: The oxygen sensing electrode can be used to monitor the oxygen levels in air and water, which is crucial for environmental monitoring and pollution control.
• Medical applications: The electrode can be used in medical devices to monitor the oxygen levels in blood or other bodily fluids, aiding in the diagnosis and treatment of various medical conditions.
• Industrial processes: The electrode can be used in industrial processes that require monitoring and control of oxygen levels, such as in chemical reactions or fermentation processes.

Problems Solved

This technology solves several problems, such as:

• Cost and complexity: The electrode can be manufactured easily and quickly at a low cost, making it more accessible for various applications.
• Selective sensing: The electrode can selectively sense gases and dissolved oxygen, providing accurate and reliable measurements.
• Long-term stability: The electrode exhibits long-term stability, ensuring consistent performance over extended periods of use.

Benefits

The benefits of this technology include:

• Cost-effective manufacturing: The use of a trace amount of noble metal and the 3D printing process make the electrode manufacturing process cost-effective.
• Selective sensing: The electrode can selectively sense gases and dissolved oxygen, allowing for specific and accurate measurements.
• Long-term stability: The electrode exhibits long-term stability, reducing the need for frequent replacements or recalibrations.
• Versatile applications: The electrode can be used in various fields, including environmental monitoring, medical applications, and industrial processes.

Original Abstract Submitted

the present invention relates to a metal doped organic framework-based catalyst, and an oxygen sensing electrode using same, wherein the 3d oxygen sensing electrode is manufactured easily and quickly at a low cost by using a trace amount of noble metal, by means of a polymer/graphene/nanocatalyst composition prepared by 3d printing and nanocatalyst synthesis on the basis of a metal doped organic framework and the 3d oxygen sensing electrode is capable of selectively sensing gases and dissolved oxygen and exhibits long-term stability.