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Technological applications of superconductivity

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Technological applications of superconductivity include:

Low-temperature superconductivity

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Magnetic resonance imaging and nuclear magnetic resonance

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The biggest application for superconductivity is in producing the large-volume, stable, and high-intensity magnetic fields required for magnetic resonance imaging (MRI) and nuclear magnetic resonance (NMR). This represents a multi-billion-US$ market for companies such as Oxford Instruments and Siemens. The magnets typically use low-temperature superconductors (LTS) because high-temperature superconductors are not yet cheap enough to cost-effectively deliver the high, stable, and large-volume fields required, notwithstanding the need to cool LTS instruments to liquid helium temperatures. Superconductors are also used in high field scientific magnets.

Particle accelerators and magnetic fusion devices

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Particle accelerators such as the Large Hadron Collider can include many high field electromagnets requiring large quantities of LTS. To construct the LHC magnets required more than 28 percent of the world's niobium-titanium wire production for five years, with large quantities of NbTi also used in the magnets for the LHC's huge experiment detectors.[2]

Conventional fusion machines (JET, ST-40, NTSX-U and MAST) use blocks of copper. This limits their fields to 1-3 Tesla. Several superconducting fusion machines are planned for the 2024-2026 timeframe. These include ITER, ARC and the next version of ST-40. The addition of High Temperature Superconductors should yield an order of magnitude improvement in fields (10-13 tesla) for a new generation of Tokamaks.[3]

High-temperature superconductivity

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The commercial applications so far for high-temperature superconductors (HTS) have been limited by other properties of the materials discovered thus far. HTS require only liquid nitrogen, not liquid helium, to cool to superconducting temperatures. However, currently known high-temperature superconductors are brittle ceramics that are expensive to manufacture and not easily formed into wires or other useful shapes.[4] Therefore, the applications for HTS have been where it has some other intrinsic advantage, e.g. in:

  • low thermal loss current leads for LTS devices (low thermal conductivity),
  • RF and microwave filters (low resistance to RF), and
  • increasingly in specialist scientific magnets, particularly where size and electricity consumption are critical (while HTS wire is much more expensive than LTS in these applications, this can be offset by the relative cost and convenience of cooling); the ability to ramp field is desired (the higher and wider range of HTS's operating temperature means faster changes in field can be managed); or cryogen free operation is desired (LTS generally requires liquid helium, which is becoming more scarce and expensive).

HTS-based systems

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HTS has application in scientific and industrial magnets, including use in NMR and MRI systems. Commercial systems are now available in each category.[5]

Also one intrinsic attribute of HTS is that it can withstand much higher magnetic fields than LTS, so HTS at liquid helium temperatures are being explored for very high-field inserts inside LTS magnets.

Promising future industrial and commercial HTS applications include Induction heaters, transformers, fault current limiters, power storage, motors and generators, fusion reactors (see ITER) and magnetic levitation devices.

Early applications will be where the benefit of smaller size, lower weight or the ability to rapidly switch current (fault current limiters) outweighs the added cost. Longer-term as conductor price falls HTS systems should be competitive in a much wider range of applications on energy efficiency grounds alone. (For a relatively technical and US-centric view of state of play of HTS technology in power systems and the development status of Generation 2 conductor see Superconductivity for Electric Systems 2008 US DOE Annual Peer Review.)

Electric power transmission

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The Holbrook Superconductor Project, also known as the LIPA project, was a project to design and build the world's first production superconducting transmission power cable. The cable was commissioned in late June 2008 by the Long Island Power Authority (LIPA) and was in operation for two years. The suburban Long Island electrical substation is fed by a 2,000 foot (600 m) underground cable system which consists of about 99 miles (159 km) of high-temperature superconductor wire manufactured by American Superconductor chilled to −371 °F (−223.9 °C; 49.3 K) with liquid nitrogen,[dubiousdiscuss] greatly reducing the cost required to deliver additional power.[6] In addition, the installation of the cable bypassed strict regulations for overhead power lines, and offered a solution for the public's concerns[which?] on overhead power lines.[7][failed verification]

The Tres Amigas Project was proposed in 2009 as an electrical HVDC interconnector between the Eastern Interconnection, the Western Interconnection and Texas Interconnection.[8] It was proposed to be a multi-mile, triangular pathway of superconducting electric cables, capable of transferring five gigawatts of power between the three U.S. power grids. The project lapsed in 2015 when the Eastern Interconnect withdrew from the project. Construction was never begun.[9]

Section of superconducting cable, as installed in Essen, Germany

Essen, Germany has the world's longest superconducting power cable in production at 1 kilometer. It is a 10 kV liquid nitrogen cooled cable. The cable is smaller than an equivalent 110 kV regular cable and the lower voltage has the additional benefit of smaller transformers.[10][11]

In 2020, an aluminium plant in Voerde, Germany, announced plans to use superconductors for cables carrying 200 kA, citing lower volume and material demand as advantages.[12][13]

Magnesium diboride

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Magnesium diboride is a much cheaper superconductor than either BSCCO or YBCO in terms of cost per current-carrying capacity per length (cost/(kA*m)), in the same ballpark as LTS, and on this basis many manufactured wires are already cheaper than copper. Furthermore, MgB2 superconducts at temperatures higher than LTS (its critical temperature is 39 K, compared with less than 10 K for NbTi and 18.3 K for Nb3Sn), introducing the possibility of using it at 10-20 K in cryogen-free magnets or perhaps eventually in liquid hydrogen.[citation needed] However MgB2 is limited in the magnetic field it can tolerate at these higher temperatures, so further research is required to demonstrate its competitiveness in higher field applications.

Trapped field magnets

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Exposing superconducting materials to a brief magnetic field can trap the field for use in machines such as generators. In some applications they could replace traditional permanent magnets.[14][15][16]

Notes

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  1. ^ Fischer, Martin. New Path to 10 MW Renewable Energy World, 12 October 2010. Retrieved: 14 October 2010.
  2. ^ Superconductors Face the Future. 2010
  3. ^ ITER Magnets
  4. ^ See for example L. R. Lawrence et al: "High Temperature Superconductivity: The Products and their Benefits" Archived 2014-09-08 at the Wayback Machine (2002) Bob Lawrence & Associates, Inc.
  5. ^ See for example HTS-110 Ltd and Paramed Medical Systems .
  6. ^ Gelsi, Steve (2008-07-10). "Power firms grasp new tech for aging grid". Market Watch. Retrieved 2008-07-11.
  7. ^ Eckroad, S. (December 2012). "Superconducting-Power-Equipment" (PDF). Technology*Watch*2012 – via EPRI.
  8. ^ "Superconductor Electricity Pipelines to be Adopted for America's First Renewable Energy Market Hub". 2009-10-13. Retrieved 2009-10-25.
  9. ^ Boswell-Gore, Alisa (13 March 2021). "Tres Amigas: What could have been". The Eastern New Mexico News. Retrieved 28 May 2023.
  10. ^ Williams, Diarmaid (7 January 2016). "Nexans success in Essen may see roll-out in other cities". Power Engineering. Retrieved 6 July 2018.
  11. ^ "Ein Leuchtturmprojekt für den effizienten Stromtransport" (PDF) (in German). Archived from the original (PDF) on 2014-11-08.
  12. ^ "Demo200". Retrieved 2020-03-07.
  13. ^ "Trimet in Voerde setzt auf nachhaltige Supraleitertechnologie" (in German). 2020-02-04. Retrieved 2020-03-07.
  14. ^ "Trapped Field Magnet | Center for Electromechanics". cem.utexas.edu. Retrieved 2023-11-09.
  15. ^ "Physicists discover flaws in superconductor theory". phys.org. Retrieved 2023-11-09.
  16. ^ Wen, H.M.; Lin, L.Z.; Xiao, L.Y.; Xiao, L.; Jiao, Y.L.; Zheng, M.H.; Ren, H.T. (2000). "Trapped field magnets of high-T/sub c/ superconductors". IEEE Transactions on Applied Superconductivity. 10 (1): 898–900. Bibcode:2000ITAS...10..898W. doi:10.1109/77.828376. S2CID 38030007.