In adiabatic container with adiabatic piston contains `4gm N_(2)` gas and `0.8 gm` He gas are separated by a weakly conducting light partition. Both piston and partition are free ro move. Initial temperature of `N_(2)` and He gases are `'3 T_(0)'` and `'T_(0)'` respectively. Initially system is at Rest and in equilibrium. Final temperature of the gas is.

In an adiabatic expansion of a gas initial and final temperatures are T_(1) and T_(2) respectively, then the change in internal energy of the gas is

A cylindrical adiabatic container of total volume 2V_(0) divided into two equal parts by a conducting piston which is free to move as shown in figure. Each part containing identical gas at pressure P_(0) . Initially temperature of left and right part is 4T_(0) and T_(0) respectively. An external force is applied on the piston of area 'A' to keep the piston at rest. The value of external force required when thermal equilibrium is reached is.

A gas is found to obey the law P^(2)V = constant . The initial temperature and volume are T_(0) and V_(0) . If the gas expands to a volume 3 V_(0) , its final temperature becomes

A gas is found to obey the law p^(2) V = constant. The initial temperature and volume are T_(0) and V_(0) . If the gas expands to a volume 3V_(0) , its final temperature becomes

Ten moles of a diatomic perfect gas are allowed to expand at constant pressure. The initial volume and temperature are V_0 and T_0 respectively. If 7/2RT_0 heat is transferred to the gas, then the final volume and temperature are

A thermally insulated vessels contains two liquids with initial temperature T_(1) and T_(2) and specific heats C_(0) and 2C_(0) , separted by a non conducting partition. The partition is removed, and the difference between the initial temperature of one of the liquids and the temperature T established in the vessel turns out to be equal to half the difference between the initial temperatures of the liquids. Determine the ratio of M_(1)//M_(2) of the masses of the liquids.

A cylindrical container is divided into three parts by two tight fitting pistons. The pistons are connected by a spring. The region between the pistons is vacuum and the other two parts have same number of moles of an ideal gas. Initially, both the gas chambers are at temperature T_(0) and the spring is compressed by 1 m. Length of both gas chambers is 1 m in this position. Now the temperature of the left and right chambers are raised to (4T_(0))/(3) and (5T_(0))/(3) respectively. Find the final compression in the spring in equilibrium. Assume that the pistons slide without friction