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High-purity copper is a metal material with high conductivity, good thermal conductivity, high ductility and corrosion resistance. It is used in superconducting, semiconductor targets, aerospace and high-end manufacturing, new energy technology, electronics and electrical industries. , scientific research and experimental equipment, thermal management systems and other fields.
Basic parameters:
| RRR value: | ~3000 |
| purity: | Cu=99.9999+% |
| Total impurities: | ≤1ppm |
| Appearance color: | Copper gold |
| Product Specifications: | 5*5cm, 10*10cm, 20*20cm |
| Oxygen content | <1ppm |
| Silver content | Below the minimum detection limit |
| Comply with 74 full-element testing standards of national standards | |
Product application industry:
6N copper has significant advantages in the superconducting industry due to its low resistivity, high thermal conductivity, excellent processability and extremely low impurity content. It can reduce energy loss, improve heat dissipation efficiency, avoid impurities interfere with superconducting performance, and enhance composite materials. The mechanical strength and thermal stability of the machine can reduce the magnetoresistive effect in low temperature environments, so it is widely used in the manufacturing of superconducting cables, magnets and other key equipment.
The extremely high purity of 6N copper effectively reduces interference from impurities during semiconductor deposition, ensuring high quality and consistency of film materials. Low impurity content helps to form a more uniform and denser copper film, improves electrical and mechanical properties, and meets the strict requirements of advanced semiconductor devices for material performance. The high conductivity of 6N copper promotes efficient migration of electrons in semiconductor devices, improving the overall performance and response speed of the device. When copper targets are used in processes such as physical vapor deposition (PVD), high conductivity reduces energy loss and improves deposition efficiency.
6N copper can quickly conduct and dissipate the generated heat, prevent equipment from overheating and ensure the stable operation of the system under high temperature environment. The high purity of 6N copper reduces impurities, significantly improves corrosion resistance, and adapts to variable and harsh environmental conditions in aerospace, such as high humidity, high salt and extreme temperatures. In a highly corrosive environment, 6N copper can effectively prevent material deterioration, extend the service life of equipment and components, and reduce maintenance costs.
The conductivity of 6N copper is close to the theoretical limit of pure copper, suitable for efficient current transmission, significantly reducing energy losses, and is especially suitable for high-end connectors, printed circuit boards (PCBs) and long-distance power transmission applications. High purity reduces impurity content, significantly improves the corrosion resistance of copper, and extends the life of the material. It can still maintain excellent performance in harsh environments.
The extremely high purity of 6N copper ensures that variable interference caused by impurities is reduced in scientific research experiments, and improves the accuracy and reliability of experimental results. The low impurity content ensures consistency of material properties and facilitates repetitive experiments and standardized research. In experiments requiring high-precision electrical measurements and signal transmission, 6N copper provides stable and efficient conductivity, reducing signal loss and noise.
6N copper has extremely high thermal conductivity, which can quickly conduct and distribute heat generated by electronic equipment effectively, prevent equipment from overheating and ensure stable operation of the system. Uniform heat conduction performance helps optimize the heat distribution inside the equipment, reduce the formation of hot spots, and improve overall heat dissipation efficiency. 6N copper has good ductility and toughness, which is easy to process into complex radiator shapes, meeting the design needs of various equipment.
High-purity copper is a metal material with high conductivity, good thermal conductivity, high ductility and corrosion resistance. It is used in superconducting, semiconductor targets, aerospace and high-end manufacturing, new energy technology, electronics and electrical industries. , scientific research and experimental equipment, thermal management systems and other fields.
Basic parameters:
| RRR value: | ~3000 |
| purity: | Cu=99.9999+% |
| Total impurities: | ≤1ppm |
| Appearance color: | Copper gold |
| Product Specifications: | 5*5cm, 10*10cm, 20*20cm |
| Oxygen content | <1ppm |
| Silver content | Below the minimum detection limit |
| Comply with 74 full-element testing standards of national standards | |
Product application industry:
6N copper has significant advantages in the superconducting industry due to its low resistivity, high thermal conductivity, excellent processability and extremely low impurity content. It can reduce energy loss, improve heat dissipation efficiency, avoid impurities interfere with superconducting performance, and enhance composite materials. The mechanical strength and thermal stability of the machine can reduce the magnetoresistive effect in low temperature environments, so it is widely used in the manufacturing of superconducting cables, magnets and other key equipment.
The extremely high purity of 6N copper effectively reduces interference from impurities during semiconductor deposition, ensuring high quality and consistency of film materials. Low impurity content helps to form a more uniform and denser copper film, improves electrical and mechanical properties, and meets the strict requirements of advanced semiconductor devices for material performance. The high conductivity of 6N copper promotes efficient migration of electrons in semiconductor devices, improving the overall performance and response speed of the device. When copper targets are used in processes such as physical vapor deposition (PVD), high conductivity reduces energy loss and improves deposition efficiency.
6N copper can quickly conduct and dissipate the generated heat, prevent equipment from overheating and ensure the stable operation of the system under high temperature environment. The high purity of 6N copper reduces impurities, significantly improves corrosion resistance, and adapts to variable and harsh environmental conditions in aerospace, such as high humidity, high salt and extreme temperatures. In a highly corrosive environment, 6N copper can effectively prevent material deterioration, extend the service life of equipment and components, and reduce maintenance costs.
The conductivity of 6N copper is close to the theoretical limit of pure copper, suitable for efficient current transmission, significantly reducing energy losses, and is especially suitable for high-end connectors, printed circuit boards (PCBs) and long-distance power transmission applications. High purity reduces impurity content, significantly improves the corrosion resistance of copper, and extends the life of the material. It can still maintain excellent performance in harsh environments.
The extremely high purity of 6N copper ensures that variable interference caused by impurities is reduced in scientific research experiments, and improves the accuracy and reliability of experimental results. The low impurity content ensures consistency of material properties and facilitates repetitive experiments and standardized research. In experiments requiring high-precision electrical measurements and signal transmission, 6N copper provides stable and efficient conductivity, reducing signal loss and noise.
6N copper has extremely high thermal conductivity, which can quickly conduct and distribute heat generated by electronic equipment effectively, prevent equipment from overheating and ensure stable operation of the system. Uniform heat conduction performance helps optimize the heat distribution inside the equipment, reduce the formation of hot spots, and improve overall heat dissipation efficiency. 6N copper has good ductility and toughness, which is easy to process into complex radiator shapes, meeting the design needs of various equipment.
