Magnetism and Magnetic effects of Electric current current

Name: Magnetism and Magnetic effects of Electric current current
Rating: 2.3 (3 reviews)

Magnetic fields , Magnetic field lines , Magnetic materials , current carrying wires as a source of magnetic field

Created byGagan Deep Ahuja

Last updated 5/2022

English

What you'll learn

Magnetism , magnetic materials magnetic field lines and their properties
Diamagnetic paramagnetic and ferromagnetic materials and their properties ,Domain theory of ferromagnetism
Biot Savart law ,Magnetic field due to straight wire , Magnetic field due to circular wire , semicircular wire and circular arc
Amperes circuital law
Motion of a charged particle in a magnetic field
Cyclotron principal , construction and working
Force on a current carrying wire placed in a magnetic field
Force between two parallel wires carrying current
Suspension type and western type galvanometer
Magnetism

Course content

1 section • 19 lectures • 5h 21m total length

Introduction4:03
Magnetism Introduction14:33
Explore the history of magnetism, from ancient natural magnets to artificial and electromagnets, and learn about magnetic dipoles, Earth's magnetism, and the basic properties of magnets.
Properties of magnets12:29
Explore the properties of magnets, including the nonexistence of magnetic monopoles, the dipole nature of magnets, induction, attraction and repulsion, and the magnetic pole strength and inverse-square force law.
Magnetic field lines and their properties17:19
Explore magnetic field lines as imaginary guides to the direction and strength of fields around magnets and current-carrying wires, including uniform and non-uniform fields and their closed-loop nature.
Magnetic dipole moment4:23
Current loop as a magnetic dipole6:53
Explore how a current loop acts as a magnetic dipole, with its magnetic moment m = I A directed by the current orientation, analogous to a bar magnet.
Diamagnetic and paramagnetic substance17:00
Ferromagnetism and Domain theory15:30
Delve into ferromagnetic substances, their domains and exchange coupling, and compare boundary displacement with domain rotation under external fields, including Kutty law and magnetic susceptibility.
Oersted Experiment4:52
The Oersted experiment demonstrates that current produces a magnetic field that deflects a compass needle, revealing the link between electricity and magnetism and the magnetic effects of electric current.
Biot Savart Law and magnetic field due to straight wire50:44
Magnetic field due to circular wire7:27
Explore how to find the magnetic field at the center of a circular wire loop and identify its direction at the central point.
Magnetic field on the axis of circular wire43:19
Analyze how a circular wire creates a magnetic field along its axis, with the field perpendicular to the wire's plane and magnitude dependent on the radius and current.
Motion on a charged particle moving in a unifprm magnetic field17:50
Explore how a charged particle moves in a uniform magnetic field, tracing a circular path under a perpendicular force, with the orbit radius growing as speed increases.
Problem based on motion of a charged particle moving in a magnetic field4:50
Explore how a charged particle entering a magnetic field experiences magnetic force that bends its path into a semicircle, with the magnetic field providing the centripetal motion.
Force between two parallel wires carrying current7:22
Torque on a current carrying rectangular coil placed in a magnetic field9:10
Examine how a current-carrying rectangular coil experiences torque in a magnetic field, as opposing side forces produce rotation and reveal the coil's directional behavior.
Suspension type moving coil galvanometer26:11
Explore the suspension type moving coil galvanometer, a precision instrument that detects and measures small currents using a coil in a magnetic field, with mirror-based light deflection for accuracy.
Voltage and currtent sensitivity of galvanometer10:04
Explain voltage sensitivity and current sensitivity of a galvanometer, and how coil area and magnetic field influence deflection, including the trade-offs with resistance and weight.
Conversion of galvanometer into ammeter and voltmeter47:27

Requirements

Prior knowlege of vectors and calculus is required at certain places

Description

Magnes, while tending his flock, noticed that pieces of a certain type of rock were attracted to the nails on his shoes and to his metal staff .

This phenomenon was called magnetism and, as time passed, further studies of the behaviour of this rock revealed several curious effects.

For example, a piece of this rock could either attract or repel another similar piece . This effect seemed to result from two different magnetic effects, so investigators thought that there must be two different types of “magnetic ends,” or poles, on the rock.

This observation led to the law of magnetism, which states:

Like magnetic poles repel and unlike poles attract each other.

In 1269, Pierre de Maricourt was mapping the position of a magnetized needle placed at various positions on the surface of a spherical piece of this rock. He observed that the directions of the needle formed a pattern that encircled the rock, like meridian lines, and converged at two points on opposite ends of the rock. When this rock was then suspended by a string, the two converging points tended to align along Earth’s north–south axis. This property of the rock earned it the name “lodestone” or “leading stone.” Maricourt called the end pointing northward the north-seeking or north pole and the end pointing southward the south-seeking or south pole. All magnets have both poles. Lodestone, which contains the mineral magnetite (Fe3O4), was later used in the development of compass technology

Magnetism plays a major role in your everyday life.

All electric motors, with uses as diverse as powering refrigerators, starting cars, and moving elevators, contain magnets. Magnetic resonance imaging (MRI) has become an important diagnostic tool in the field of medicine, and the use of magnetism to explore brain activity is a subject of contemporary research and development.

Other applications of magnetism include computer memory, levitation of high-speed trains, the aurora borealis, and, of course, the first important historical use of magnetism: navigation. You will find all of these applications of magnetism linked by a small number of underlying principles.

In this course , you will learn that both the internal properties of an object and the movement of charged particles can generate a magnetic field, and you will learn why all magnetic fields have a north and south pole.

You will also learn how magnetic fields exert forces on objects, resulting in the magnetic alignment that makes a compass work.

You will learn how we use this principle to weigh the smallest of subatomic particles with precision and contain superheated plasma to facilitate nuclear fusion.

Who this course is for:

This course is for students looking to stregthen their concepts of Magnetism and magnetic effects of current for AP Physics course C:Magnetic fields
Students in grade XI and XII
Students preparing for advance Placement exam or any university admission test
Students preparing for JEE,NEET,CBSE exam
Students preparing for various engineering or medical entrance examinations