[" The heavier block in an Atwood machine has a mass "],[" twice that of the lighter one.The tension in the string "],[" is "16^(-0)N" when the system is set into motion.Find the "],[" decrease in the gravitational potential energy during the "],[" first second after the system is released from rest."],[" The two blocks in "]

The heavier bock in an atwood machine has a mass twice that of the lighter one. The tension in the stirng is 16.0 N when the sytem is set into motion. Find the decrease in the gravitational potential energy during the first second after the system is releaed from rest.

The two blocks in an Atwood machine have masses 2.0 kg and 3.0 kg. Find the work done by gravity during the fourth second after the system is released from rest.

The two blocks in an Atwood machine have masses 2.0 kg and 3.0 kg. Find the work done by gravity during the fourth second after the system is released from rest.

The two blocks in an Atwood machine have masses 2.0 kg and 3.0 kg. Find the work done by gravity during the fourth second after the system is released from rest.

Two blocks of different masses are hanging on two ends of a string passing over a frictionless pulley. The heavier block has a mass twice as that of the lighter one. The tension in the string is 60N The decrease in potential energy during the first second after the system is released 2K Joule. Then find the value of K. (Take g=10m/s^(2))

In the system shown in figure, the block A is released from rest. Find Tension in the string.

Two blocks A and B of equal mass m are connected through a massless string and arranged as shown in the figure. Friction is absent everywhere. When the system is released from rest

In the ideal atwood machine arrangement shown, what is the change in kinetic energy of the system in (1)/(sqrt2) second of their motion starting from rest ?