A gas mixture consists of 3 moles of oxygen and 5 moles of argon at temperature T. Considering only translational and rotational modes, the total internal energy of the system is :

A gas mixture coinsists of (2) moles of oxygen and (4) moles of argon at temperature (T). Neglecting all vibrational modes, the total internal energy of the system is (jee 1999) (a) 4 RT (b) 15 RT ( c) 9 RT (d) 11 RT.

A gas mixture consists of 2.0 moles of oxygen and 4.0 moles of neon at temperature T. Neglecting all vibrational modes, calculate the total internal energy of the system . (0xygen has two rotational modes).

A gas mixture consists of 2 moles of oxygen and 4 of Argon at temperature T. Neglecting all vibrational modes, the total internal energy of the system is

A gas mixture consists of 2 moles of oxygen and 4 of Argon at temperature T. Neglecting all vibrational modes, the total internal energy of the system is

A gas mixture consists of 3 moles of oxygen and 5 moles of argon at temperature T . Assuming the gases to be ideal and the oxygen bond to be rigid, the total internal energy ( in units of RT ) of the mixture is :

A gaseous mixture consists of 16 g of O_2 and 16 g of He at temperature T. Neglecting the vibrational modes, total internal energy of the system is

3 mole of O2 mixed with 5 moles of Argon at temperature T. Find total internal energy of system

Find total internal energy of 3 moles of hydrogen gas at temperature T .

A mixture of ideal gases has 2 moles of He, 4 moles of oxygen and 1 mole of ozone at absolute temperature T. The internal energy of mixture is

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