Horseshoe magnet

A horseshoe magnet is either a permanent magnet or an electromagnet made in the shape of a horseshoe (in other words, in a U-shape). The permanent kind has become the most widely recognized symbol for magnets.^[1]^: 2 It is usually depicted as red and marked with 'North' and 'South' poles.^[1]^: 3 Although rendered obsolete in the 1950s by squat, cylindrical magnets made of modern materials,^[1]^: 3,467 horseshoe magnets are still regularly shown in elementary school textbooks.^[1]^: 3 Historically, they were a solution to the problem of making a compact magnet that does not destroy itself in its own demagnetizing field.^[1]^: 2^[2]

History

In 1819, it was discovered that passing electric current through a piece of metal deflected a compass needle. Following this discovery, many other experiments surrounding magnetism were attempted. These experiments culminated in William Sturgeon wrapping wire around a horseshoe-shaped piece of iron and running electric current through the wires creating the first horseshoe magnet.^[3]

This was also the first practical electromagnet and the first magnet that could lift more mass than the magnet itself when the seven-ounce magnet was able to lift nine pounds of iron.^[3]^[4] Sturgeon showed that he could regulate the magnetic field of his horseshoe magnet by increasing or decreasing the amount of current being run through the wires.^[4] This would lay the groundwork for development of the electrical telegraph and the future of world-wide telecommunications for the next century and more.^[4]

Shape

The shape of the magnet was originally created as a replacement for the bar magnet as it makes the magnet stronger.^[5] A horseshoe magnet is stronger because both poles of the magnet are closer to each other and in the same plane which allows the magnetic lines of flux to flow along a more direct path between the poles and concentrates the magnetic field.^[6]

The shape of the horseshoe magnet also drastically reduces its demagnetization over time.^[7] This is due to coercivity also known as the "staying magnetized" ability of a given magnet.^[7] Coercivity is weaker in disc or ring shapes, slightly stronger in cylinder or bar shapes, and strongest in horseshoe shapes.^[6]^[7] To increase the coercivity of horseshoe magnets, steel keepers or magnet keepers are used.^[7] A magnetic field holds its strength best when the entire magnetic field is given the ability to loop through a ferromagnetic substance instead of air.^[8] The nearness of the horseshoe magnet’s poles facilitates the ability to use these magnet keepers more easily than other types of magnets.^[8]

A horseshoe magnet made of AlNiCo, an iron alloy. The attached iron bar is a magnet keeper used to prevent demagnetization.
Magnetic field of a horseshoe magnet. The field is greatest where the lines are densest, around the poles (lower)
Alnico horseshoe magnet used in a magnetron tube in an early microwave oven. About 3 in (8 cm) long.
Assortment of AlNiCo horseshoe magnet shapes available from a manufacturer in 1956.
A rectangular horseshoe magnet.

References

^ ^a ^b ^c ^d ^e Coey, J. M. D. (2010). Magnetism and Magnetic Materials. Cambridge University Press. ISBN 978-0-511-67743-4.
^ "Why are Magnets Shaped like Horseshoes?". K&J Magnetics, Inc. Archived from the original on 24 December 2022. Retrieved 23 February 2023.
^ ^a ^b "Magnetism and Electromagnetism". Spark Museum. SPARK Museum of Electrical Invention. Retrieved 3 January 2021.
^ ^a ^b ^c Bellis, Mary (23 February 2019). "William Sturgeon and the Invention of the Electromagnet". ThoughtCo. Retrieved 3 January 2021.
^ "The Various Shapes of Magnets and Their Uses". Apex Magnets. Retrieved 3 January 2021.
^ ^a ^b "Temperature and Neodymium Magnets". K&J Magnetics. K&J Magnetics, Inc. Retrieved 3 January 2021.
^ ^a ^b ^c ^d "Why are Magnets Shaped like Horseshoes?". K&J Magnetics. K&J Magnetics, Inc. Retrieved 3 January 2021.
^ ^a ^b "Demagnetizing a Steel Nail". Sciencing. Retrieved 3 January 2021.

External links

Media related to Horseshoe magnets at Wikimedia Commons

[Coey_Magnetism-1] Coey, J. M. D. (2010). Magnetism and Magnetic Materials. Cambridge University Press. ISBN 978-0-511-67743-4.

[kjmagnetics-2] "Why are Magnets Shaped like Horseshoes?". K&J Magnetics, Inc. Archived from the original on 24 December 2022. Retrieved 23 February 2023.

[Spark_Museum-3] "Magnetism and Electromagnetism". Spark Museum. SPARK Museum of Electrical Invention. Retrieved 3 January 2021.

[ThoughtCo-4] Bellis, Mary (23 February 2019). "William Sturgeon and the Invention of the Electromagnet". ThoughtCo. Retrieved 3 January 2021.

[Apex-5] "The Various Shapes of Magnets and Their Uses". Apex Magnets. Retrieved 3 January 2021.

[K&J-1-6] "Temperature and Neodymium Magnets". K&J Magnetics. K&J Magnetics, Inc. Retrieved 3 January 2021.

[K&J-2-7] "Why are Magnets Shaped like Horseshoes?". K&J Magnetics. K&J Magnetics, Inc. Retrieved 3 January 2021.

[Sciencing-8] "Demagnetizing a Steel Nail". Sciencing. Retrieved 3 January 2021.

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v t e Magnetism
Magnetic response	diamagnetism superdiamagnetism paramagnetism superparamagnetism Van Vleck paramagnetism
Magnetic states	altermagnetism antiferromagnetism ferrimagnetism ferromagnetism superferromagnetism ferromagnetic superconductor helimagnetism metamagnetism mictomagnetism spin glass amorphous magnetism spin ice

Horseshoe magnet

History

Shape

References

External links

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