In the system shown in figure `m_(1) gt m_(2)`. System is held at rest by thread BC. Just after the thread BC is burnt.

In the system in the figure m_(1)gtm_(2) system is held at rest by thread BC . Just after the thread BC is burnt:

In the system shown in fig. m_(1) gt m_(2) . The system is held at rest by thread BC. Now thread BC is burnt. Answer the following: Just after burning the thread, what is the acceleration of m_(2) ?

In the system shown in fig. m_(1) gt m_(2) . The system is held at rest by thread BC. Now thread BC is burnt. Answer the following: Before burnig the thread, what are the tensions in spring and thread BC, respectively?

For the system shown in figure , to be in equilibrium , determine mass m .

The system shown in figure is initially in equilibrium. What is the acceleration of B just after the string connecting B to ground is cut ?

For the system shown in fog. m_(1) gt m_(2) gtm_(3) gt m_(4) . Initially, the system is at rest in equilibrium condition., if the string joining m_(4) and ground is cut, then just after the string is cut. Statement I: m_(1), m_(2), m_(3) remain stationary. Statement II: The value of acceleration of all the four blocks can be determined. Statement III: Only m_(4) remain stationary. Statement IV: Only m_(4) accelerates.

Wedge shown in the figure is fixed . System is released from rest (Neglect friction )

Find the mass m in the figure for the system to be at rest

A smooth block of mass m is held stationary on a smooth wedge of mass M and inclination theta as shown in figure .If the system is released from rest , then the normal reaction between the block and the wedge is

The system shown in the figure is in equilibrium at rest. The spring and string are massless Now the string is cut. Find the acceleration of the blocks just after the string is cut.