a particle moving in a circle track is given potential energy `U = -k/r` where U is potential energy and r is radius. The correct graph between speed and radius of particles will be

A particle of mass m moves in a circular orbit under the central potential field, U(r)==-C/r, where C is a positive constant. The correct radius -velocity graph of the particle's motion is.

The angular acceleration of a particle moving along a circle is given by a=ksin (theta),where "theta" is the angle turned by particle and k is constant.The centripetal acceleration of the particle in terms of k ,theta and R (radius of circle) is given by

The potential energy of a particle moving in a circular path is given by U = U_0 r^4 where r is radius of circular path. Assume bohr model to be valid. The radius of nth orbit is r prop n^(1/alpha) where alpha is

A particle is executing SHM. At a displacement y_(1) its potential energy is U_(1) and at a displacement y_(2) its potential energy is U_(2) . The potential energy of the particle at displacement (y_(1)+y_(2)) is

A particle is moving in a circular path of radius a under the action of an attractive potential U=-(k)/(2r^(2)) . Its total energy is :

The potential energy of a particle of mass 2 kg moving along the x-axis is given by U(x) = 4x^2 - 2x^3 ( where U is in joules and x is in meters). The kinetic energy of the particle is maximum at

A particle of mass m moves under the action of a central force. The potential energy function is given by U(r)=mkr^(3) Where k is a positive constant and r is distance of the particle from the centre of attraction. (a) What should be the kinetic energy of the particle so that it moves in a circle of radius a0 about the centre of attraction? (b) What is the period of this circualr motion ?

If a particle of mass m is moving in a horizontal circle of radius r with a centripetal force (-1//r^(2)) , the total energy is

A small particle of mass m , moves in such a way that the potential energy U = ar^(3) , where a is position constant and r is the distance of the particle from the origin. Assuming Rutherford's model of circular orbits, then relation between K.E and P.E of the particle is :

The kinetic energy K of a particle moving along a circle of radius R depends upon the distance S as K=betaS^2 , where beta is a constant. Tangential acceleration of the particle is proportional to