A conducting loop of area 5.0 cm^2 is pl...

A conducting loop of area 5.0 cm^2 is placed in a magnetic feld which varies sinusoidally with time as `B = B_0 sin omegat` where B_0 = 0.20 T and `omega = 300 s^(-1). The normal to the coil makes an angle of `60^@` with the field. Find (a) the maximum emf induced in the coil, (b) the emf induced at `tau = (tau/900)s` and (c) the emf indcued at ` t = (pi/600)s.

Promotional Banner

Promotional Banner

Similar Questions

Explore conceptually related problems

A conducting loop of area 5.0 cm^2 is placed in a magnetic field which varies sinusoidally with time as B = B_0 sin omegat where B_0 = 0.20 T and omega = 300 s^(-1) . The normal to the coil makes an angle of 60^@ with the field. Find (a) the maximum emf induced in the coil, (b) the emf induced at t = (pi/900)s and (c) the emf induced at t = (pi/600)s .

A conducting loop of area 5.0 cm^2 is placed in a magnetic field which varies sinusoidally with time as B = B_0 sin omegat where B_0 = 0.20 T and omega = 300 s^(-1) . The normal to the coil makes an angle of 60^@ with the field. Find (a) the maximum emf induced in the coil, (b) the emf induced at t = (pi/900)s and (c) the emf induced at t = (pi/600)s .

A conducting loop of area A is placed in a magnetic field which varies sinusoidally with time as B=B_(0)sin

A conducting looop of area 5.0cm^(2) is placed in a magnetic field which varies sinusoidally with time as B=0.2sin300t . The normal to the coil makes an angle of 60^(@) with the field. The emf induced at t=(pi//900)s

A conducting looop of area 5.0cm^(2) is placed in a magnetic field which varies sinusoidally with time as B=0.2sin300t . The normal to the coil makes an angle of 60^(@) with the field. The emf induced at t=(pi//900)s

A coil having an area A_0 is placed in a magnetic field which changes from B_0 to 4B_0 in time interval t. The emf induced in the coil will be

A conducting metal circular-wire-loop of radius r is placed perpendicular to a magnetic field which varies with time as B = B_0e^(-t//tau) , where B_0 and tau are constants, at time = 0. If the resistance of the loop is R then the heat generated in the loop after a long time (t to oo) is :

A conducting metal circular-wire-loop of radius r is placed perpendicular to a magnetic field which varies with time as B = B_0e^(-t//tau) , where B_0 and tau are constants, at time = 0. If the resistance of the loop is R then the heat generated in the loop after a long time (t to oo) is :

A conducting metal circular-wire-loop of radius r is placed perpendicular to a magnetic field which varies with time as B = B_0e^(-t//tau) , where B_0 and tau are constants, at time = 0. If the resistance of the loop is R then the heat generated in the loop after a long time (t to oo) is :

Recommended Questions

A conducting loop of area 5.0 cm^2 is placed in a magnetic feld which ...
Text Solution
|
A conducting loop of area 5.0 cm^2 is placed in a magnetic field which...
Text Solution
|
A loop of wire enclosing an area S is placed in a region where the mag...
Text Solution
|
A conducting looop of area 5.0cm^(2) is placed in a magnetic field whi...
Text Solution
|
A magnetic field of flux density 10 T act normal to a 50 turn coil of ...
Text Solution
|
A closed coil having 50 turns is rotated in a uniform magnetic field B...
Text Solution
|
The magnetic flux linked with a coil varies with time t as phi=at^(2)+...
Text Solution
|
A circular coil of area 0.1 m^(2) having 200 turns is placed in a magn...
Text Solution
|
A circular loop of radius R is placed in the uniform magnetic field. T...
Text Solution
|