When 22.5 J was added as heat to a particular ideal gas, the volume of the gas changed from 50.0 `cm^3` to 100 `cm^3` while the pressure remained at 1.00 atm. (a) By how much did the internal energy of the gas change? If the quantity of gas present was `2.00 xx 10^(-3)`mol, find (b)`C_p` and (c) `C_v`

How many moles of helium at temperature 300K and 1.00 atm pressure are needed to make the internal energy of the gas 100J?

During the expansion process the volume of the gas changes form 4m^(3) to 6m^(3) while the pressure change according to p = 30 V +100 where pressure is in Pa and volume is in m^(3) . The work done by gas in N xx 10^(2)J . Find N .

When 100J of heat is given to an ideal gas it expands from 200cm^(3) to 400cm^(3) at a constant pressure of 3 xx 10^(5) Pa . Calculate (a) the change in internal energy of the gas (b) the number of moles in the gas if the initial temperature is 400K , (c ) the molar heat capacity C_(p) at constant pressure and (d) the molar heat capacity C_(v) at constant volume. [R = (25)/(3)J//mol-K]

A gas expends from 1.5 to 6.5 L against a constant pressure of 0.5 atm and during this process the gas also absorbs 100 J of heat. The change in the internal energy of the gas is

If a gas absorbs 200J of heat and expands by 500 cm^(3) against a constant pressure of 2 xx 10^(5) N m^(-2) , then the change in internal energy is

A gas is at 1 atm pressure with a volume 800 cm^(3) . When 100 J of heat is supplied to the gas, it expands to 1L at constant pressure. The change in its internal energy is

A sample of ideal gas (gamma = 1.4) is heated at constant pressure. If an amount 140 J of heat is supplied to the gas, find (a) the changes in internal energy of the gas, (b) the work done by the gas.

One mole of an ideal monoatomic gas is heated at a constant pressure of one atmosphere from 0^(@) to 100^(@)C. Then the change in the internal energy is