What the HECK are Magnets? (Electrodynamics)

The Science Asylum

21 Nov 201807:14

Summary

TLDRThis educational video explores the relationship between electric charge and magnetic fields, debunking the myth of magnetic charge and explaining how moving electric charges create magnetic fields. It delves into the historical discovery by Hans Christian Ørsted and the subsequent Biot-Savart Law. The video also distinguishes between electromagnets and permanent magnets, linking their magnetic properties to moving charges and electron spin angular momentum. It concludes with a fascinating look at the quantum mechanics behind magnetism in materials like iron, cobalt, nickel, and gadolinium.

Takeaways

🔋 Electric charge is a measure of how much something can affect the electric field.
🧲 Unlike electric fields, magnetic fields are not affected by a separate 'magnetic charge' but by moving electric charges.
🚀 The movement of a charged particle, like a proton, can influence both electric and magnetic fields.
🌐 In 1819, Hans Christian Ørsted discovered that electric currents could affect magnetic compasses, demonstrating a link between electricity and magnetism.
🤔 The Biot-Savart Law, not Laplace's Law, describes the pattern of how a current-carrying wire affects a magnetic field.
🔗 Magnetism arises from moving charges, whether it's a single charge or many charges in a current.
🧭 Permanent magnets and electromagnets are fundamentally caused by the same principle: the movement or momentum of charges.
🌐 The Earth's magnetic field plays a role in why we label magnetic poles as north and south.
⚛️ Atoms can exhibit magnetism due to the spin angular momentum of unpaired electrons, particularly in elements like iron, cobalt, nickel, and gadolinium.
🤷‍♂️ Despite extensive study, the specific charges of particles remain a mystery, needing to be measured and incorporated into the standard model without a known underlying mechanism.

Q & A

What is the relationship between electric charge and electric fields?
-Electric charge is a measure of how much something can affect the electric field.
Does a magnetic charge exist that affects the magnetic field in the same way electric charge affects the electric field?
-No, the magnetic field is affected by electric charges, not by a separate magnetic charge.
How does a moving electric charge affect the magnetic field?
-A moving electric charge can affect the magnetic field, as demonstrated by a proton that, when moving, can influence both the electric and magnetic fields.
What did Hans Christian Ørsted discover in 1819 regarding magnetic fields and electric currents?
-Hans Christian Ørsted discovered that magnetic compasses would deflect when placed near a current-carrying wire.
Who formulated the Biot-Savart Law and what does it describe?
-The Biot-Savart Law was formulated by Jean-Baptiste Biot and Félix Savart. It describes the pattern of how a current-carrying wire affects the magnetic field.
What is the difference between an electromagnet and a permanent magnet?
-An electromagnet is created by electricity and has an electric current running through it, while a permanent magnet does not have a current running through it and retains its magnetism for a long time without an external power source.
Why do all permanent magnets have at least one north pole and one south pole?
-This is due to the basic properties of magnetic fields, which have two opposite sources that are labeled as north and south poles.
What is the role of quantum mechanics in explaining the magnetism of materials?
-Quantum mechanics is essential for understanding magnetism at the atomic and subatomic levels, particularly in explaining how electrons' angular momentum and spin contribute to magnetism.
How do the electrons in an iron atom contribute to its magnetism?
-In iron, four of the electrons have unpaired spins that line up in the same direction, contributing to the atom's magnetism.
What are the four elements that exhibit magnetism at room temperature?
-The four elements that exhibit magnetism at room temperature are Iron, Cobalt, Nickel, and Gadolinium.
What is the significance of domains in the context of magnetic materials?
-Domains are regions within magnetic materials where atoms with aligned magnetic moments are grouped together, which is necessary for the material to exhibit macroscopic magnetism.