A beam of equally charged particles after being accelerated through a voltage V enters into a magnetic field B as shown in Fig. 1.31. It is found that all the particles hit the plate between C and D. Find the ratio between the masses of the heaviest and lightest particles of the beam.

A beam of mixture of alpha particle and protons are accelerted through same potential difference before entering into the magnetic field of strength B. if r_1=5 cm then r_2 is

A charged particle, having charge q_(1) accelerated through a potential difference V enters a perpendicular magnetic field in which it experiences a force F. It V is increased to 5V, the particle will experience a force

If a charged particle of charge to mass ratio (q/m) = alpha centers in a magnetic field of strength B at a speed v=(2 alpha d) (B), then

A thin beam of charged particles in incident normally on the boundry of a region containing a uniform magnetic field as shown.The beam comprise of mono energetic alpha and beta(-) particles, each possessing a kinetic energy T .Neglecting interaction between particles of the beam, find the separation between the points on line PQ where the alpha and beta particles emerge out of the magnetic field.(express your answer in terms of T,B,alpha(2e,m_(alpha)) & beta^(-)(-e,m_(e)) ,where all terms have their usual meanings.)

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

A proton, a deutron and an alpha particle, after being accelerated through the same potential difference enter a region of uniform magnetic field vecB , in a direction perpendicular to vecB . Find the ratio of their kinetic energies. If the radius of proton's circular path is 7cm , what will be the radii of the paths of deutron and alpha particle?

Two particles X and Y with equal charges, after being accelerated throuhg 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

Two particles X and Y with equal charges, after being accelerated throuhg 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

Two particles X and Y with equal charges, after being accelerated throuhg 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

Two particles X and Y with equal charges, after being accelerated throuhg 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