Find the loss in the mass of 1 mole of an ideal monatomic gas kept in a rigid container as it cools down by `10^@C`. The gas constant `R = 8.3 J K ^(-1) mol ^(-1)`.

Calculate the volume of 1 mole of an ideal gas at STP.

Calculate the internal energy of 1 mole of an ideal gas at 250ºC.

Calculate the ratio (C_p / C_v) of oxygen from the following data . Speed of sound in oxygen (= 32g mol^(-1)) and the gas constant (R = 8.3 J K ^(-1) mol^(-1)) .

4.0 g of gas occupies 22.4 litres at NTP . The specific heat capacityof the gas at constant volume is 5.0jk^(-1) mol ^(-1) if the speed of sound in this gas at NTP is 952 ms^(-1) , then the heat capacity at constant pressure is: (Take gas constant R=8.3JK^(-1) mol^-1) .

0.32 g of oxygen is kept in a rigid container and is heated. Find the amount of heat needed to raise the temperature from 25^0 C to 35^0 C . The molar heat capacity of oxygen at constant volume is 20 J K^(-1) mol^(-1) .

Figure shows two rigid vessels A and B, each of volume 200 cm ^(3) containg an ideal gas (C_v = 12.5 JK ^(-1) mol^(-1)) . The vessels are connected to a manometer tube containing mercury. The pressure in both the vessels is 75 cm mercury and the temperature is 300k. (a) (5-0 J) of heat is supplied to the gas in the vessels.(b) (10 J) to the gas in the vessels B. Assuming no appreciable transfer of heat from A to B calculate the dufference in the heights of mercury in the two sides of the manometer. Gas constant (R = 8.3 JK^(-1) mol^(-1))

consider the cyclic process ABCA on a sample of 2.0 mol of an ideal gas as shown in the fig. temperature of the gas at A and B are 300 K and 500 k respectively. A total of 1200 J heat is withdrawn from the sample in the process. Find the work done by the gas in part BC. take R=8.3 JK^(-1) mol^(-1)

Find the mass of water vapour per cubic metre of air at temperature 300K and relative humidity 50%. The saturation vapour pressure at 300K is 3.6kPa and the gas constant R=8.3JK^(-1)mol^(-1) .