In the diagram (given below), the broken lines represent the paths followed by particles W, X, Y and Z respectively through the contant field E. The number below the field represent meters.

Suppose that the field strength E is `10 N//C` and particle Y has a charge of `-10 C`. When is the mass of particle Y

In the diagram (given below), the broken lines represent the paths followed by particles W, X, Y and Z respectively through the contant field E. The number below the field represent meters. Suppose particle Z has a charge of +2C , and is begins and end at rest. If E is 5N//C , how much work is done on particle Z

In the diagram ( given below ) the broken lines represents the paths followed by particles W,,X,Y and Z respectively through the constant field E. The numbers below the field represents meters. In previous question if the particles started from rest and all are positively charge which particles must have been acted upon by a force other than that produced by the electric field. A. W and Y B. X and Z C. X,Y and Z D. W,X,Y and Z

In the diagram (given below), the broken lines represent the paths followed by particles W, X, Y and Z respectively through the contant field E. The number below the field represent meters. If the particles are positively charged, which particles increased their electric potential energy constant, none of the particle increased their electric potential energy

The charge on a particle Y is double the charge on particle X .These two particles X and Y after being accelerated through the same potential difference enter a region of uniform magnetic field and describe circular paths of radii R_(1) and R_(2) respectively. The ratio of the mass of X to that of Y is

Write the differential equation representing the family of straight lines y=C x+5,\ w h e r e\ C is an arbitrary constant.

Two particle X and Y having equal charge, after being accelerated through the same potential difference enter a region of uniform magnetic field and describe circular paths of radii R_1 and R_2 respectively. The ratio of the mass of X to that of Y is

The cyclotron is a device which is used to accelerate charged particles such as protons, deutrons, alpha particles, etc. to very high energy. The principle on which a cyclotron works is based on the fact that an electric field can accelerate a charged particle and a magnetic field can throw it into a circular orbit. A particle of charge +q experiences a force qE in an electric field E and this force is independent of velocity of the particle. The particle is accelerated in the direction of the magnetic field. On the other hand, a magnetic field at right angles to the direction of motion of the particle throws the particle in a circular orbit in which the particle revolves with a frequency that does not depend on its speed. A modest potential difference is used as a sources of electric field. If a charged particle is made to pass through this potential difference a number of times, it will acquire an enormous by large velocity and hence kinetic energy. Which of the following cannot be accelerated in a cyclotron?

A particle of mass m=1.6xx10^-27 kg and charge q=1.6xx10^-19C enters a region of uniform magnetic field of stregth 1 T along the direction shown in figure. The speed of the particle is 10^7 m//s a. The magnetic field is directed along the inward normal to the plane of the paper. The particle leaves the region of the fiedl at the point F . Find the distasnce EF and the angle theta. b. If the direction of the field is along the outward normal to the plane of the paper find the time spent by the particle in the regin of the magnetic field after entering it at E .

A particle of mass m and charge q is placed at rest in a uniform electric field E and then released, the kinetic energy attained by the particle after moving a distance y will be

A particle of mass m = 1.6 X 10^(-27) kg and charge q = 1.6 X 10^(-19) C moves at a speed of 1.0 X10^7 ms^(-7) . It enters a region of uniform magnetic field at a point E, as shown in The field has a strength of 1.0 T. (a) The magnetic field is directed into the plane of the paper. The particle leaves the region of the filed at the point F. Find the distance EF and the angle theta. (b) If the field is coming out of the paper, find the time spent by the particle in the regio the magnetic feld after entering it at E .