A standing wave `y=2A sinkx cos omegat` is setup in the wire `AB` fixed at both ends by two vertical walls (see the figure). the region between the wall contains a constant magnetic field `B`. Now answer the following questions.
In the above question, the time when the emf becomes maximum for the first time is

A standing wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: The wire is found to vibrate in the third harmonic. The maximum emf induced is

A standing wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: The wire is found to vibrate in the third harmonic. The maximum emf induced is

A standing wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: In which of the following modes the emf induced in AB is always zero?

A stsnding wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . Now answer the following question: In which of the following modes the emf induced in AB is always zero?

A standing wave y = 2A sin kx cos omegat is set up in the wire AB fixed at both ends by two vertical walls (see Fig. 3.197). The region between the walls contains a constant magnetic field B . The wire is found to vibrate in the third harmonic. Now answer the following question: In the above qestion, the time when the emf becomes maximum for the time is

On a stationary block of mass 2kg a horizontal forces F starts acting at t = 0 whose veriation with time is shown in figure .The coefficient of friction between the block and ground is 0.5 New answer the following question Find the velocity of the block when for the firsst time its acceleration become zero

A closed current-carrying loop having a current I is having area A. Magnetic moment of this loop is defined as vec(mu) = vec(IA) where direction of area vector is towards the observer if current is flowing in anticlockwise direction with respect to the observer. If this loop is placed in a uniform magnetic field vec(B) , then torque acting on the loop is given by vec(tau) = vec(mu) xx vec(B) . Now answer the following questions: Let ring in the above question is having a radius R and a charge Q is uniformly distributed over it. Ring is rotated with a constant angular velocity (omega) as mentioned above. Torque acting on the ring due to magnetic force is

A model rocket rests on a frictionless horizontal surface and is joined by a string of length l to a fixed point so that the rocket moves in a horizontal circular path of radius l . The string will break if its tensiion exceeds a value T . The rocket engine provides a thrust F of constant magnitude along the rocket's direction of motion. the rocket has a mass m that does not change with time. Answer the following questions based on the above passage. What distance does the rocket travel between the time t_(1) when the string breaks and the time 2t_(1) ? The rocket engine continues of operate after the string breaks.

The Betatron was the first important machine for producing high energy electrons. The action of the betatron depends on the same fundamental principle as that of the transformer in which an alternating current applied to a primary coil induces an altermating current usually with higher or lower voltage in the secondary coil. In the betatron secondary coil is replaced by a doughnut shaped vacuum chamber.Electron produced in the doughnut from a hot filament, are given a preliminary acceleration by the application of an electric field having potential difference of 20 kV to 70 kV , when an alternating magnetic field is applied parallel to the axis of the tube, two effects are produced (1) an electromotive force is produced in the electron orbit by the changing magnetic flux that gives an additional energy to the electrons (2) a radial force is produced by the action of magnetic field whose direction is perpendicular to the electron velocity. Which keeps the electron moving in a circular path. Conditions are arranged such that the increasing magnetic field keeps the electron in a circular orbit of constant radius. The mathematical relation between the betatron parameters to ensure the above condition is called BETATRON condition. If the orbit radius of the circular path traced by the electron is R , magnetic field is B , speed of the electron is v , mass of the electron is m , charge on the electron is e and phi is the flux within the orbit of radius R . Then answer the following questions based on the above comprehension. What is the tangential force acting on the electron ?

Estimation of frequency of a wave forming a standing wave represented by y = A sin kx cos t can be done if the speed and wavelength are known using speed = "Frequency" xx "wavelength" . Speed of motion depends on the medium properties namely tension in string and mass per unit length of string . A string may vibrate with different frequencies . The corresponding wavelength should be related to the length of the string by a whole number for a string fixed at both ends . Answer the following questions: A string fixed at both ends having a third overtone frequency of 200 Hz while carrying a wave at a speed of 30 ms^(-1) has a length of