Two cylinders A and B have been placed in contact on an incline. They remain in equilibrium. The dimensions of the two cylinders are same. Which cylinder has larger mass?

Two cylinder A and B having piston conneted by massless rod (as shown in figure). The cross-sectional area two cylinders are same & equal to 'S'.The cylinder A contains m gm of an ideal gas at Pressure P & temperature T_(0) The cylinder B contain identical gas at same temperature T_(0) but has different mass. The piston is held at the state in the position so that volume of gas in cylinder A & cylinder B are same and is equal to V_(0) . The walls & piston of cylinder A are thermally insulated, whereas cylinder B is maintained at temperature T_(0) reservoir. The whole system is in vacuum. Now the piston is slowly released and it moves towards left & machanical equilibrium is reached at the state when the volume of gas in cylinder A becomes V_(0)/2 Then (here gamma for gas =1.5) If work done by gas in cylinder B is W_(B) & work done by gas in cylinder A is W_(A) then

Two cylinder A and B having piston conneted by massless rod (as shown in figure). The cross-sectional area two cylinders are same & equal to 'S'.The cylinder A contains m gm of an ideal gas at Pressure P & temperature T_(0) The cylinder B contain identical gas at same temperature T_(0) but has different mass. The piston is held at the state in the position so that volume of gas in cylinder A & cylinder B are same and is equal to V_(0) . The walls & piston of cylinder A are thermally insulated, whereas cylinder B is maintained at temperature T_(0) reservoir. The whole system is in vacuum. Now the piston is slowly released and it moves towards left & machanical equilibrium is reached at the state when the volume of gas in cylinder A becomes V_(0)/2 Then (here gamma for gas =1.5) The mass of gas in cylinder B

Two cylinder A and B having piston conneted by massless rod (as shown in figure). The cross-sectional area two cylinders are same & equal to 'S'.The cylinder A contains m gm of an ideal gas at Pressure P & temperature T_(0) The cylinder B contain identical gas at same temperature T_(0) but has different mass. The piston is held at the state in the position so that volume of gas in cylinder A & cylinder B are same and is equal to V_(0) . The walls & piston of cylinder A are thermally insulated, whereas cylinder B is maintained at temperature T_(0) reservoir. The whole system is in vacuum. Now the piston is slowly released and it moves towards left & machanical equilibrium is reached at the state when the volume of gas in cylinder A becomes V_(0)/2 Then (here gamma for gas =1.5) What will be the compressive force in conneting rod at equilibrium

Two cylinder A and B having piston conneted by massless rod (as shown in figure). The cross-sectional area two cylinders are same & equal to 'S'.The cylinder A contains m gm of an ideal gas at Pressure P & temperature T_(0) The cylinder B contain identical gas at same temperature T_(0) but has different mass. The piston is held at the state in the position so that volume of gas in cylinder A & cylinder B are same and is equal to V_(0) . The walls & piston of cylinder A are thermally insulated, whereas cylinder B is maintained at temperature T_(0) reservoir. The whole system is in vacuum. Now the piston is slowly released and it moves towards left & machanical equilibrium is reached at the state when the volume of gas in cylinder A becomes V_(0)/2 Then (here gamma for gas =1.5 ) The change in internal energy of gas in cylinder A

A cylinder of radius R has been placed in a corner as shown in the fig. A wedge is pressed against the cylinder such that its inclined surfaces touches the cylinder at a height of (2R)/(5) from thw ground. Now the wedge is pushed to the left at a constant speed V = 15 m//s . With what speed will the cylinder move?

The radii of the base of two cylinders A and B are in the ratio 3:2 and their height in the ratio n:1. If the volume of cylinder A is 3 times that of cylinder B, the value of n is

Three identical smooth cylinders, each of mass m and radius r are resting in equilibrium within a fixed smooth cylinder of radius R (only a part of this cylinder has been shown in the fig). Find the largest value of R in terms of r for the small cylinders to remain in equilibrium.

Two bodies a ring and a solid cylinder of same material are rolling down without slipping an inclined plane. The radii of the bodies are same. The ratio of velocity of the centre of mass of the bottom of the inclined plane of the ring to that of the cylinder is (sqrt(x))/(2) . Then, the value of x is ……………….

A uniform cylinder of mass m lies on a fixed plane inclined at a angle theta with the horizontal. A light string is tied to the cylinder at the rightmost point, and a mass m hangs from the string as shown. Assume that the coefficient of friction between the cylinder and the incline plane is sufficiently large to prevent slipping. for the cylinder to remain static the value of m is