Home” Science” Korean Video Shows Possible Weak Magnetic Locking Effects
Among the Korean scientists dealing with space temperature level superconductors reveals a sample with some possible magnetic locking results. The phenomenon happened when he discovered and eliminated a part of the sample that was felt to have strong diamagnetism. He does not understand if the impact can be described by Lenz’s law. He believes it is better to flux spinning.
In July 2023, South Korean scientists released a paper declaring to have actually established a room-temperature superconductor called LK-99. In March, 2024, teacher Kim Hyun-tak of the College of William and Mary provided joint research study on PCPOSOS, a product the scientists declare to be a space temperature level and regular pressure superconductor. PCPOSOS is a product with more copper and sulfur in the chemistry than the initial Lead apatite LK-99.
SCTL is another laboratory and business dealing with Kim Hyun-tak on the declared room-temperature and space pressure superconductor product. The SCTL group has the brand-new video revealing a little sample with weak magnetic impacts. The impacts are weak since the samples are not pure products. The results are fascinating as those who slam the work have actually stated that the samples are insulators or semiconductors. This presentation is proof that these are diamagnetic or superconducting products. The suspension of the sample in a locked position that is not touching the routine magnets is not a typical impact for a routine copper metal next to a routine magnet.
Lenz’s law states that when the north pole of the bar magnet is approaching the coil, the caused existing circulations in such a method regarding make the side of the coil nearest the pole of the bar magnet itself a north pole to oppose the approaching bar magnet. Upon withdrawing the bar magnet from the coil, the caused present reverses itself, and the near side of the coil ends up being a south pole to produce a bring in force on the declining bar magnet.
Flux pinning is a phenomenon that takes place when flux vortices in a type-II superconductor are avoided from moving within the bulk of the superconductor, so that the electromagnetic field lines are “pinned” to those areas. The superconductor should be a type-II superconductor since type-I superconductors can not be permeated by electromagnetic fields Some type-I superconductors can experience the results of flux pinning if they are thin enough. If the product’s density is equivalent to the London penetration depth, the electromagnetic field can travel through the product. The act of magnetic penetration is what makes flux pinning possible. At greater electromagnetic fields (above lower important field however listed below upper crucial field) the superconductor permits magnetic flux to go into in quantized packages surrounded by a superconducting existing vortex
Brian Wang is a Futurist Thought Leader and a popular Science blog writer with 1 million readers each month. His blog site Nextbigfuture.com is ranked # 1 Science News Blog.