A block of mass `m = 1 kg` is released from point `A` along a smooth track as shown. Part `AB` is circular with radius `r_(1) = 4 m` and circular at `C` with radius `r_(2)`. Height of point `A` is `h_(1) = 2m` and of `c` is `h_(2) = 1m (g = 10 m//s^(2))`.
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The work done by gravitational force from `A` to `C` is

A block of mass m = 1 kg is released from point A along a smooth track as shown. Part AB is circular with radius r_(1) = 4 m and circular at C with radius r_(2) . Height of point A is h_(1) = 2m and of c is h_(2) = 1m (g = 10 m//s^(2)) . . The force exerted by block on the track at B is

A block of mass m = 1 kg is released from point A along a smooth track as shown. Part AB is circular with radius r_(1) = 4 m and circular at C with radius r_(2) . Height of point A is h_(1) = 2m and of c is h_(2) = 1m (g = 10 m//s^(2)) . . The minimum safe value of r_(2) so that the block does not fly off the track at C is

A block of mass m is released from a height R on the frictionless incline as shown. The incline leads to a circle of radius R/2. The maximum height attained by the block is

A particle of mass m is released from point A as shown in the gigure. Would it loop the loop if H=4r? What is the force on the circular track when it is at point (a) B, (b) C?

A particle of mass m is released from a height H on a smooth curved surface which ends into a vertical loop of radius R , as shown. Choose the correct alernative(s) if H=2R .

A body of mass 10 kg is dropped to the ground from a height of 10 metres. The work done by the gravitational force is (g=9.8m//sec^(2))

A block of mass 1 kg slides down a vertical curved track that is one quadrant of a circle of radius 1m. Its speed ast the the bottom si 2 m//s . The work done by frictional force is :

Figure. Shown a ring of mass M_(1) ans a sphere of mass M_(2) separated by a distance sqrt(3)R . A small object of mass m is displaced from A to B. Find the work done by gravitational forces.