4 g of an ideal gass (Vapour dencity=20) is taken in a bulb of `10 dm^3`volume at a temperature of T K. The bulb is placed in a thermostat maintained at a temperature 125°C more than the initial. To maintain original pressure, 0.8 g of gas has to be removed, then the value of T is

4 g of an ideal has (vapour densely = 20) is taken in abulbe od 10 dm^3 volume, at a temperature of T K.The bulb is present on thermostat maintained at a temperature 125°C more than the initial. To maintain original pressure, 0.8 g of gas has to be removed, then the value of T is

At a temperature T K, the pressure of 4.0g argon in a bulb is p. The bulb is put in a bath having temperature higher by 50K than the first one 0.8g of argon gas had to be removed to maintained original pressure. The temperature T is equal to

At a temperature T, K , the pressure of 4.0 gm argon in a bulb is P . The bulb is put in a bath having temperature higher by 50 K than the first one 0.8 of argon gas had to be removed to maintain original pressure. The temperature T is

Four moles of an ideal gas is initially in state A having pressure 2 xx 10^(5) N//m^(2) and temperature 200 K . Keeping the pressure constant the gas is taken to state B at temperature of 400K . The gas is then taken to a state C in such a way that its temperature increases and volume decreases. Also from B to C , the magnitude of dT//dV increases. The volume of gas at state C is equal to its volume at state A . Now gas is taken to initial state A keeping volume constant. A total 1000 J of heat is withdrawn from the sample of the cyclic process . Take R=8.3 J// K// mol . The volume of gas at state C is

Four moles of an ideal gas is initially in a state A having pressure 2xx10^(5)N//m^(2) and temperature 200 K . Keeping pressure constant the gas is taken to state B at temperature of 400K. The gas is then taken to a state C in such a way that its temperature increases and volume decreases. Also from B to C, the magnitude of (dT)/(dV) increases. The volume of gas at state C is eaual to its volume at state A. Now gas is taken is initial state A keeping volume constant. A total of 1000 J heat is rejected from the sample in the cyclic process. Take R=8.3J//K//mol . Which graph between temperture T and volume V for the cyclic process is correct.

Two moles of an ideal gas at temperature T_(0) = 300 K was cooled isochorically so that the pressure was reduced to half. Then, in an isobaric process, the gas expanded till its temperature got back to the initial value. Find the total amount of heat absorbed by the gas in the processs

Four moles of an ideal gas is initially in a state A having pressure 2xx10^(5)N//m^(2) and temperature 200 K . Keeping pressure constant the gas is taken to state B at temperature of 400K. The gas is then taken to a state C in such a way that its temperature increases and volume decreases. Also from B to C, the magnitude of (dT)/(dV) increases. The volume of gas at state C is eaual to its volume at state A. Now gas is taken is initial state A keeping volume constant. A total of 1000 J heat is rejected from the sample in the cyclic process. Take R=8.3J//K//mol . The work done by the gas along path B to C is

A vessel of volume V_(0) contains an ideal gas at pressure p_(0) and temperature T. Gas is continuously pumped out of this vessel at a constant volume-rate dV/dt=r keeping the temperature constant, The pressure inside the vessel. Find (a) the pressure of the gas as a function of time,(b) the time taken before half the original gas is pumped out.

A flask is filled with 13 g of an ideal gas at 27^(@)C and its temperature is raised to 52^(@)C . The mass of the gas that has to be released to maintain the temperature of the gas in the flask at 52^(@)C , the pressure remaining the same is

A flask is filled with 13 g of an ideal gas at 27^(@)C and its temperature is raised to 52^(@)C . The mass of the gas that has to be released to maintain the temperature of the gas in the flask at 52^(@)C , the pressure remaining the same is