The potential energy of a particle under a conservative force is given by `U ( x) = ( x^(2) -3x)` J. The equilibrium position of the particle is at

Potential energy of a particle at position x is given by U = (x^2 - 4x) J . Which of the following is equilibrium position of the particle?

Potential energy of a particle at position x is given by U=x^(2)-5x . Which of the following is equilibrium position of the particle?

The potential energy U(x) of a particle moving along x - axis is given by U(x)=ax-bx^(2) . Find the equilibrium position of particle.

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 conservative force field is given by U=ax^(2)-bx where, a and b are positive constants. Find the equilibrium position and discuss whether the equilibrium is stable, unstable or neutral.

The potential energy of a particle in motion along X axis is given by U = U_0 - u_0 cos ax. The time period of small oscillation is

The potential energy for a conservative force system is given by U=ax^(2)-bx . Where a and b are constants find out (a) The expression of force (b) Potential energy at equilibrium.

The potential energy for a conservative force system is given by U=ax^(2)-bx . Where a and b are constants find out (a) The expression of force (b) Potential energy at equilibrium.

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

The potential energy of a particle in a conservative field is U =a/r^3-b/r^2, where a and b are positive constants and r is the distance of particle from the centre of field. For equilibrium, the value of r is