How do Magnets Work - PHYSICS!

James Lincoln

22 Nov 201204:24

Summary

TLDRThis video explores the mystery of magnetism, starting with the historical discovery of magnetic minerals in Magnesia, Greece. It explains how magnetized iron has aligned magnetic domains, which can be manipulated to create or destroy magnetism. The role of electrons' spin in magnetism is highlighted, with iron, nickel, and cobalt being unique due to their paired electrons with parallel spins. The video concludes by emphasizing the quantum mechanical phenomenon of electron spin alignment in everyday magnets.

Takeaways

🧲 Magnets are naturally occurring minerals found in Magnesia, Greece, that can attract or repel each other.
🔍 Unmagnetized iron is made up of randomly oriented tiny crystal magnets called domains.
📚 Magnetization aligns the domains in iron, creating a north and south side, thus making it a magnet.
🔊 The flipping of magnetic domains can be made audible through a coil of wire and a speaker.
🌐 The magnetism in metals like iron, cobalt, and nickel is related to electron movement.
🔬 Electrons have a property called spin, which, when aligned, contributes to the magnetic properties of certain elements.
📊 The alignment of electron spins in iron, nickel, and cobalt is due to an unusual pairing of valence electrons with parallel spins.
🔥 Heating can disrupt the magnetic domains in a magnet, causing the loss of magnetism.
🔋 A coil of wire with a looping current acts like a bar magnet, influencing the direction of compasses.
🧬 Magnetism is a quantum mechanical effect that is observable in everyday life, particularly in iron, nickel, and cobalt.

Q & A

What is the origin of the term 'magnet'?
-The term 'magnet' originates from the ancient Greek region of Magnesia, where naturally occurring minerals that attracted iron were found.
How are magnetic domains related to magnetism?
-Magnetic domains are tiny crystal magnets within unmagnetized iron metal that are randomly oriented. In magnetized iron, these domains align, giving the metal a north and south side, which allows it to become a magnet.
What happens to the magnetic domains during the magnetization process?
-During the magnetization process, the magnetic domains in iron flip their orientation, aligning in a specific direction, which results in the material becoming a magnet.
How can the flipping of magnetic domains be made audible?
-The flipping of magnetic domains can be made audible by placing a small piece of nickel inside a coil of wire and bringing a strong magnet close to it, causing any rapid changes in the magnetic field to sound on a speaker.
Which elements are known to be magnetic besides iron?
-Besides iron, cobalt and nickel are also magnetic elements, and their proximity on the periodic table indicates that magnetism is a result of electron behavior.
How does heating affect the magnetic domains in a magnet?
-Heating can destroy the alignment of magnetic domains in a magnet, causing the magnet to lose its magnetism.
What property of electrons is responsible for magnetism?
-Electron spin, the intrinsic angular momentum of electrons, is responsible for magnetism. The alignment of these electron spins results in the magnetic properties of certain materials like iron, nickel, and cobalt.
Why do iron, nickel, and cobalt exhibit magnetism?
-Iron, nickel, and cobalt exhibit magnetism because they have an unusual double veence (valence) electron configuration where their two valence electrons have parallel spins, which is a rare circumstance.
What was the outcome of the experiment conducted by Albert Einstein and vonder deas to test the cause of magnetism?
-The experiment conducted by Albert Einstein and vonder deas to test whether orbiting electrons caused magnetism resulted in negative findings, leading to further investigation and the later discovery of electron spin.
How do the magnetic properties of a bar magnet compare to a coil of wire with a looping current?
-A coil of wire with a looping current acts just like a bar magnet, causing compasses to align with the magnetic field created by the current, pointing out of North and into South.
What is the significance of quantum mechanical effects in everyday life as it relates to magnetism?
-Quantum mechanical effects, such as the alignment of electron spins, are significant in everyday life as they are the fundamental reason behind the existence of magnets, which have numerous applications in technology and industry.