In the figure the variation of potential energy of a particle of mass `m = 2kg` is represented w.r.t. its x-coordinate. The particle moves under the effect of this conservative force along the x-axis.

If the particle is released at the origin then

In the figure, the variation of potential energy of a particle of mass m = 2kg is represented with respect to its x-coordinate. The particle moves under the effect of this conservative force along the X-axis. If the particle is released at the origin, then

In the figure, the variation of potential energy of a particle of mass m = 2kg is represented with respect to its x-coordinate. The particle moves under the effect of this conservative force along the X-axis. If the particle is released at x = 2 + Delta where Delta rarr 0 (it is positive), then its maximum speed in subsequent motion will be

In the figure the variation of potential energy of a particle of mass m = 2kg is represented w.r.t. its x-coordinate. The particle moves under the effect of this conservative force along the x-axis. x = - 5m and x = 10 m position of the particle are respectively of

In the figure the variation of potential energy of a particle of mass m=2kg is represented w.r.t. its x-coordinate. The particle moves under the effect of this conservative force along the x-axis. Which of the following statements are correct about the particle:

In figure, the variation of potential energy of a particle of mass m=2kg is represented w.r.t its x-coordinate. The particle moves under the effect of the conservative force along the x-axis. Which of the following statements is incorrect about the particle?

The potential energy of a particle moving along x-axis is given by U = 20 + 5 sin (4 pi x) , where U is in J and x is in metre under the action of conservative force :

In the figure the variations of componets of acceleration of particles of mass 1kg is shown w.r.t. time. The initial velocity of the particle is vec(u)=(-3 hati+4hatj) m/s. the total work done by the resultant force on the particles in time intervals from t=0 to t=4 seconds is :

Force acting on a particle moving in the x-y plane is vecF=(y^2hati+xhatj)N , x and y are in metre. As shown in figure, the particle moves from the origin O to point A (6m, 6m) . The figure shows three paths, OLA, OMA, and OA for the motion of the particle from O to A. Now consider another situation. A force vecF=(4hati+3hatj)N acts on a particle of mass 2kg . The particle under the action of this force moves from the origin to a point A (4m, -8m) . Initial speed of the particle, i.e., its speed at the origin is 2sqrt6ms^-1 . Figure shows three paths for the motion of the particle from O to A. If the potential energy at O is 16J , the potential energy at A will be