Niobium alloy

A niobium alloy is one in which the most common element is niobium.

Alloys used for the production of other alloys

The most common commercial niobium alloys are ferroniobium and nickel-niobium, produced by thermite reduction of appropriate mixtures of the oxides; these are not usable as engineering materials, but are used as convenient sources of niobium for specialist steels and nickel-based superalloys. Going via an iron-niobium or nickel-niobium alloy avoids problems associated with the high melting point of niobium.

Superconducting alloys

Niobium–tin superconducting wire from the ITER fusion reactor, which is currently under construction.

Niobium-tin and Niobium-titanium are essential alloys for the industrial use of superconductors, since they remain superconducting in high magnetic fields (30 T for Nb₃Sn, 15 T for NbTi); there are 1200 tons of NbTi in the magnets of the Large Hadron Collider, whilst Nb₃Sn is used in the windings of almost all hospital MRI machines.

Aerospace rivets

Niobium-titanium alloy, of the same composition as the superconducting one, is used for rivets in the aerospace industry; it is easier to form than CP titanium, and stronger at elevated (> 300°C) temperatures.

Refractory alloys

Niobium-1% zirconium is used in rocketry and in the nuclear industry. It is regarded as a low-strength alloy.^[1]^[2]

C-103, which is 89% Nb, 10% Hf and 1% Ti, is used for the rocket nozzle of the Apollo service module and the Merlin vacuum^[3] engines; it is regarded as a medium-strength alloy. It is typically produced using gas atomization or plasma atomization techniques.^[4] It is particularly used in additive manufacturing (3D printing) and powder metallurgy processes.^[5] Due to its corrosion resistance and high thermal efficiency, C103 helps reduce material waste and environmental pollution.^[6]

High-strength alloys include C-129Y (10% tungsten, 10% hafnium, 0.1% yttrium, balance niobium), Cb-752 (10% tungsten, 2.5% zirconium), and the even higher strength C-3009 (61% niobium, 30% hafnium, 9% tungsten); these can be used at temperatures up to 1650°C with acceptable strength, though are expensive and hard to form.

Niobium alloys in general are inconvenient to weld: both sides of the weld must be protected with a stream of inert gas, because hot niobium will react with oxygen and nitrogen in the air. It is also necessary to take care (e.g. hard chrome-plating of all copper tooling) to avoid copper contamination.

References

^ Yoder, G.; Carbajo, J.; Murphy, R.; Qualls, A.; Sulfredge, C.; Moriarty, M.; Widman, F.; Metcalf, K.; Nikitkin, M. (September 2005). TECHNOLOGY DEVELOPMENT PROGRAM FOR AN ADVANCED POTASSIUM RANKINE POWER CONVERSION SYSTEM COMPATIBLE WITH SEVERAL SPACE REACTOR DESIGNS (PDF) (Report). U.S. Department of Energy. Retrieved Aug 20, 2024.
^ Roche, T. (1 October 1965). Evaluation of Niobium-Vanadium Alloys for Application in High-Temperature Reactor Systems (PDF) (Technical report). Oak Ridge National Laboratory. doi:10.2172/4615900. ORNL-TM-1131. Archived from the original (PDF) on 7 January 2014. Retrieved 7 January 2014.
^ Hafnium (PDF). 6th Annual Cleantech & Technology Metals Conference. Toronto: Alkane Resources Ltd. 15–16 May 2017. Archived from the original (PDF) on 2017-09-18. Retrieved 2020-12-06.
^ Philips, N.R.; Carl, M.; Cunningham, N.J. (2020). "New Opportunities in Refractory Alloys". Metallurgical and Materials Transactions. 51: 3299–3310. doi:10.1007/s11661-020-05803-3.
^ Mireles, Omar; Gao, Youping; Philips, Noah. Additive Manufacture of Refractory Alloy C103 for Propulsion Applications (PDF) (Report). NASA. Retrieved Aug 20, 2024.
^ "Overview of C103 Spherical Powder: Composition, Properties, Applications". Stanford Advanced Materials. Retrieved Aug 20, 2024.

[1] Yoder, G.; Carbajo, J.; Murphy, R.; Qualls, A.; Sulfredge, C.; Moriarty, M.; Widman, F.; Metcalf, K.; Nikitkin, M. (September 2005). TECHNOLOGY DEVELOPMENT PROGRAM FOR AN ADVANCED POTASSIUM RANKINE POWER CONVERSION SYSTEM COMPATIBLE WITH SEVERAL SPACE REACTOR DESIGNS (PDF) (Report). U.S. Department of Energy. Retrieved Aug 20, 2024.

[2] Roche, T. (1 October 1965). Evaluation of Niobium-Vanadium Alloys for Application in High-Temperature Reactor Systems (PDF) (Technical report). Oak Ridge National Laboratory. doi:10.2172/4615900. ORNL-TM-1131. Archived from the original (PDF) on 7 January 2014. Retrieved 7 January 2014.

[3] Hafnium (PDF). 6th Annual Cleantech & Technology Metals Conference. Toronto: Alkane Resources Ltd. 15–16 May 2017. Archived from the original (PDF) on 2017-09-18. Retrieved 2020-12-06.

[4] Philips, N.R.; Carl, M.; Cunningham, N.J. (2020). "New Opportunities in Refractory Alloys". Metallurgical and Materials Transactions. 51: 3299–3310. doi:10.1007/s11661-020-05803-3.

[5] Mireles, Omar; Gao, Youping; Philips, Noah. Additive Manufacture of Refractory Alloy C103 for Propulsion Applications (PDF) (Report). NASA. Retrieved Aug 20, 2024.

[6] "Overview of C103 Spherical Powder: Composition, Properties, Applications". Stanford Advanced Materials. Retrieved Aug 20, 2024.

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