A particle of mass 4 gm. Lies in a potential field given by `V = 200x^(2) + 150` ergs/gm. Deduce the frequency of vibration.

A particle of mass 10gm is placed in a potential field given by V = (50x^(2) + 100)J//kg . The frequency of oscilltion in cycle//sec is

A particle of mass 100 gm moves in a potential well given by U = 8 x^(2) - 4x + 400 joule. Find its acceleration at a distance of 25 cm from equilibrium in the positive direction

A particle in a certain conservative force field has a potential energy given by V=(20xy)/z . The force exerted on it is

The gravitational potential in a region is given by, V = 200(X + Y) J//kg . Find the magnitude of the gravitational force on a particle of mass 0.5 kg placed at the orgin.

The kinetic energy of a particle of mass m moving with speed v is given by K=(1)/(2)mv^(2) . If the kinetic energy of a particle moving along x-axis varies with x as K(x)=9-x^(2) , then The region in which particle lies is :

A particle of mass m moves in a one dimensional potential energy U(x)=-ax^2+bx^4 , where a and b are positive constant. The angular frequency of small oscillation about the minima of the potential energy is equal to

The potential energy function of a particle due to some gravitational field is given by U=6x+4y . The mass of the particle is 1kg and no other force is acting on the particle. The particle was initially at rest at a point (6,8) . Then the time (in sec). after which this particle is going to cross the 'x' axis would be:

The potential energy of a particle of mass 2 kg moving in a plane is given by U = (-6x -8y)J . The position coordinates x and y are measured in meter. If the particle is initially at rest at position (6, 4)m, then

A partical of mass m is moving along the x-axis under the potential V (x) =(kx^2)/2+lamda Where k and x are positive constants of appropriate dimensions . The particle is slightly displaced from its equilibrium position . The particle oscillates with the the angular frequency (omega) given by

A charged particle of mass m and charge q is accelerated through a potential differences of V volts. It enters of uniform magnetic field B which is directed perpendicular to the direction of motion of the particle. The particle will move on a circular path of radius