Internal energy of `n_(1)` mol of hydrogen of temperature `T` is equal to the internal energy of `n_(2)` mol of helium at temperature `2T`. The ratio `n_(1) // n_(2)` is

Internal energy of n_1 moles of hydrogen at temperature 150 K is equal to the in ternal energy of n_2 moles of helium at temperature 300 K The ratio of n_1//n_2 is

Internal energy of n moles of helium at temperature T_1 K is equal to the internal energy of 2n moles of oxygen gas at temperature T_2 K then the value of T_1 /T_2 will be

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

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

Calculate the change in internal energy of 3 .0 mol of helium gas when its temperature is increased by 2. 0 K .

The internal energy of 10 g of nitrogen at N. T. P. is about

The average rotational kinetic energy of hydrogen molecule at a temperature T is E . The average translational kinetic energy of helium at same temperature will be:

The average kinetic energy of O_(2) at a particular temperatures is 0.768 eV. The average kinetic energy of N_(2) molecules in eV at the same temperature is

The ratio of translational and rotational kinetic energies at 100K temperature is 3:2 . Then the internal energy of one mole gas at that temperature is (R=8.3j//"mol"-K]

Average K.E. of CO_(2) at 27^(@)C is E. the average kinetic energy of N_(2) at the same temperature will be