What is magnetic effect of electric current?
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Magnetic Effect of Electric Current
Magnetic Effect of Electric Current – A magnetic field is a force field that is created by magnetic dipoles and moving electric charges, and it exerts a force on other nearby moving charges and magnetic dipoles. Magnetic Field is a vector quantity because it has both magnitude and direction.
Magnetic Field Lines
A magnetic field line or lines of forces shows the strength of a magnet and the direction of a magnet’s force. It was discovered by Michael Faraday to visualize the magnetic field.
Direction of Field Lines
Magnetic field lines are directed from south pole to north pole inside the magnet and from north pole to south pole outside the magnet.
Strength of Magnetic Field Lines
A straight current-carrying conductor has a magnetic field in the shape of concentric circles around it. The magnetic field of a straight current-carrying conductor can be visualized by magnetic field lines.
The direction of a magnetic field produced due to a current-carrying conductor rely upon the same direction in which the current is flowing
The direction of the electric field gets reversed if the direction of electric current changes.
Let us understand Magnetic Effect of Electric Current using a simple experiment:
Magnetic Effects of Electric Current
Suppose a straight current-carrying conductor is hung vertically, and an electric current is flowing from north to south i.e from up to down. In this situation, the direction of the magnetic field will be clockwise. And if the same current is flowing from south to north through the same conductor, the direction of the magnetic field will be anti-clockwise.
The direction of the magnetic field in electric current through a straight conductor can be represented by using the the Right-Hand Thumb Rule.
Magnetic Effects of Electric Current
Right-Hand Thumb rule
Assume that you are holding a straight current-carrying conductor in your right hand such that the thumb points towards the direction of the current. Then your fingers will wrap around the conductor in the direction of field lines of the magnetic field.
The Right-Hand Thumb rule is also known as Maxwell’s corkscrew rule. If we consider ourselves driving a corkscrew in the direction of the current, then the direction of the corkscrew is in the direction of the magnetic field.
Right-Hand Thumb rule
Magnetic Field Due to Flow of Current through a Circular Loop
The magnetic field produced in a circular current carrying conductor is the same as that of the magnetic field due to a straight current-carrying conductor and the current-carrying circular loop will behave like a magnet.
Magnetic Field Due to Flow of Current through a Circular Loop
The magnetic field lines in a current-carrying circular loop would be in the shape of concentric circles, and at the centre of the circular wire, field lines will become straight and perpendicular to the plane of the coil.
The direction of the magnetic field in a circular loop can be recognized using Right-Hand Thumb Rule
Magnetic Field due to flow of current in a Solenoid
A solenoid is a tightly wound helical coil of wire whose diameter is small compared to its length.
Magnetic Field due to flow of current in a Solenoid
Solenoid
The magnetic field produced by the current-carrying solenoid is similar to a bar magnet. One end of a solenoid behaves as a south pole and the other end behaves as a north pole. The magnetic field produced inside a solenoid is parallel which is similar to a bar magnet.
The strong magnetic force produced by a solenoid can be used to magnetize a piece of magnetic material. The magnet so formed is known as an electromagnet.
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