Two blocks, with masses `m_(1) 2.5 kg` and `m_(2) = 14 kg`, approach each other along a horizontal, frictionless track, The initial velocities of the blocks are `v_(1) = 12.0 m//s` to the right an d`v_(2) = 3.4 m//s` to the left. The two blocks then collide and stick together. Which of the graph could represent the force of block `1` on block `2` during the collision ?

Two blocks of masses m_(1) =1kg and m_(2) = 2kg are connected by a spring of spring constant k = 24 N/m and placed on a frictionless horizontal surface. The block m_(1) is imparted an initial velocity v_(0) = 12cm/s to the right. The amplitude of osciallation is

Two blocks of mass m_(1) and m_(2) are moving along a smooth horizontal floor. A non-ideal spring is attached at the back of mass m_(2) . Initial velocities of the blocks are u_(1) and u_(2) as shown, with u_(1) gt u_(2) . After collision the two blocks were found to be moving with velocities V_(1) and V_(2) respectively. Find the ratio of impulse (on each block) during the deformation phase of the spring and that during its restoration phase. [By non ideal spring we mean that it does not completely regain its original shape after deformation. You can neglect the mass of the spring.]

Two blocks with masses m_(1)=3kg and m_(2) = 4kg are touching each other on a frictionless table, as shown in figure-2.33. If the force shown acting on m_(1) is 5 N (a) What is the acceleration of the two blocks and (b) How hard does m_(1) push against m_(1) ? [0.714 m//s^(2),2.85 N]

Three block of masses m_(1),m_(2) and m_(3) kg are placed in contact with each other on a frictionless table. A force F is applied on the heaviest mass m_(1) , the acceleration of m_(2) will be

Two blocks of masses 2 kg and 1 kg are in contact with each other on a frictionless table. When a horizontal force of 3.0 N is applied to the block of mass 2 kg the value of the force of contact between the two blocks is:

Two blocks of mass m = 1 kg and M = 2 kg are in contact on a frictionless table. A horizontal force F(= 3N) is applied to m. The force of contact between the blocks, will be-

Three blocks of masses m_(1)=2kg m_(2)=3kg and m_(3)=4 kg are in contact with each other on a frictionless horizontal surface as shown in (a) Find (a) horizontal force F needed to push the block as one unit with an acceleration of 2m//s^(2) (b) the resultant force on each block and (c) the magnitude of contact forces between blocks.

Two blocks of masses m_(1) and m_(2) are placed in contact with each other on a horizontal platform. The coefficient of friction between the platform and the two blocks is the same. The platform moves with an acceleration. The force of interaction between the blocks is :

Two block of masses m_(1) and m_(2) are connected as shown in the figure. The acceleration of the block m_(2) is: