A ring shaped tube contain two ideal gases with equal masses and relative molar masses `M_1=32 and M_2=28.`
The gases are separated by one fixed partition and another movable stopper S which can move freely without friction inside the ring. The angle `alpha` as shown in the figure is ...... degrees.

A ring shaped tube contain two ideal gases with equal masses and relative molar masses M_1=32 and M_2=28. The gases are separated by one fixed partion and another movable stopper S which can move freely without friction inside the ring. The angle alpha as shown in the figure is ...... degrees.

A ring - shaped tube contains two ideal gases with equal masses and relative molar masses M_(1)=32 and M_(2)=28 . The gases are separated by one fixed partition and another movable stoper S which can move freely without friciton inside the ring . What is the value of the angel alpha (in degree) at equilibrium ?

Two monatomic ideal gases 1 and 2 of molecular masses m_(1) and m_(2) repectively are enclosed in separate containers kept at the same temprature. The ratio of the of sound in gas 1 to that in gas 2 is given by

Two monoatomic ideal gases 1 and 2 of molecular masses m^(1) and m​^(2) respectively are enclosed in separate containers kept at the same temperature. The ratio of the speed of sound in gas 1 to that in gas 2 is given by :-

Two blocks of masses m_(1) and m_(2) are connected by a string of negligible mass which pass over a frictionless pulley fixed on the top of an inclined plane as shown in figure. The coefficient of friction between m_(1) and plane is mu .

One end a light spring of natural length d and spring constant k ( = mg //d) is fixed on a rigid support and the other end is fixed to a smoth ring of mass m which can slide without friction on a vertical rod fixed at a distance d from the support. Initially , the spring makes an angle of 37^(@) with the horizontal as shown in the figure. The system is released from rest. The speed of the ring at the same angle subtended downward will be

A small particle of mass m moving inside a heavy, hollow and straight tube along the tube axis undergoes elastic collision at two ends. The tube has no friction and it is closed at one end by a flat surface while the other end is fitted with a heavy movable flat piston as shown in figure. When the distance of the piston from closed end is L = L_0 the particle speed is v = v_0 The piston is moved inward at a very low speed V such that V

One end of a light spring of natural length 4m and spring constant 170 N/m is fixed on a rigid wall and the other is fixed to a smooth ring of mass (1)/(2) kg which can slide without friction in a verical rod fixed at a distance 4 m from the wall. Initially the spring makes an angle of 37^(@) with the horizontal as shown in figure. When the system is released from rest, find the speed of the ring when the spring becomes horizontal.

In the figure, a container is shown to have a movable (without friction) piston on top. The container and the piston are all made of perfectly insulated material allowing no heat transfer between outside and inside the container. The container is divided into two compartments by a rigid partition made of a thermally conducting material that allows slow transfer of heat. The lower compartment of the container is filled with 2 moles of an ideal monatomic gas at 700K and the upper compartment is filled with 2 moles of an ideal diatmoic gas at 400K. The heat capacities per mole of an ideal monatomic gas are C_V=3/2R, C_P=5/2R, and those for an ideal diatomic gas are C_V=5/2R, C_P=7/2R, Now consider the partition to be free to move without friction so that the pressure of gasses in both compartments is the same. The total work done by the gases till the time they achives equilibrium will be