A container of volume `1m^3` is divided into two equal parts by a partition. One part has an ideal gas at 300K and the other part is vacuum. The whole system is thermally isolated from the surroundings. When the partition is removed, the gas expands to occupy the whole volume. Its temperature will now be............

A container of volume V is divided into two equal parts by a screen. One part has an ideal gas at 300K and the other part is vacuum. The whole system is thermally isolated from the surroundings. When the screen is removed, the gas expands to occupy the whole volume. Its temperature will now be .......

A sound wave passing volume 1 m^(3) is divided into two equal compartments by a partition. One of these compartments contains an ideal gas at 300 K . The other compartment is vacuum. The whole system is thermally isolated from its surroundings. The partition is removed and the gas expands to occupy the whole volume of the container. Its temperature now would be

A vessel of volume V is divided into two parts by a partition. The pressure of the gas in one part is p_(1) and that in the other part is p_(2) . If the partition is removed find the pressure of the gas in the vessel.

A container with insulating walls is divided into two equal parts by a partition fitted with a valve. One part is filled with an ideal gas at a pressure P and temperature T, whereas the other part is completely evacuated . If the valve is suddenly opened, the pressure and temperature of the gas will be

A container with insulating walls is divided into two equal parts by a partition fitted with a valve. One part is filled with an ideal gas at a pressure P and temperature T, whereas the other part is completely evacuated . If the valve is suddenly opened, the pressure and temperature of the gas will be

A thermally insulated container is divided into two parts by a screen. In one part the pressure and temperature are P and T for an ideal gas filled. In the second part it is vacuum. If now a small hole is created in the screen, then the temperature of the gas will

A rigid and insulated tank of 3m^(3) volume is divided into two compartments. One compartment of volume of 2m^(3) contains an ideal gas at 0.8314 Mpa and 400 K while the second compartment of volume of 1m^(3) contains the same gas at 8.314 Mpa and 500 K. If the partition between the two compartments is rptured, the final temperature of the gas is :

A thermally insulated chamber of volume 2V_(0) is divided by a frictionless piston of area S into two equal part A and B . Part A has an ideal gas at pressrue P_(0) and temperature T_(0) and part B is vacuum. A massless spring of force constant K is connected with the piston and the wall of the container as shown. Initially the spring is unstretched. The gas inside chamber A is allowed to expand. Let in equilibrium the spring be compressed by x_(0) . Then

A thermally insulated chamber of volume 2V_(0) is divided by a frictionless piston of area S into two equal part A and B . Part A has an ideal gas at pressrue P_(0) and temperature T_(0) and part B is vacuum. A massless spring of force constant K is connected with the piston and the wall of the container as shown. Initially the spring is unstretched. The gas inside chamber A is allowed to expand. Let in equilibrium the spring be compressed by x_(0) . Then

A cylindrical vessel made of thermally insulating material is divided into two equal parts by an insulating and. Movable piston. Both parts contain ideal monoatomic gas . The gas in the left part is supplied heat such that the volume of right part becomes one-eight of its initial volume . Work done by the gas in the right part is