Calculate the value of `gamma` for a gaseous mixture consisting `n_(1)` moles of oxygen and `n_(2)` moles of carbon dioxide. The values of `gamma` for oxygen and carbon dioxide are `gamma_(1)` and `gamma_(2)` respectively. Assume the gases to be ideal.

Calculate the value of gamma for a gaseous mixture consisting of n_(1) moles of oxygen and n_(2) moles of carbon of carbon dioxide. The values of gamma for oxygen and carbon dioxide are gamma_(1) and gamma_(2) respectively. Assume the gases to be ideal. [Hint: U_(m) = U_(1) + U_(2) and U = (nRT)/(gamma-1) ]

Calculate gamma of a gaseous mixture consisting of 3 moles of nitrogen and 2 moles of carbon dioxide.

Calculate gamma of a gaseous mixture consisting of 3 moles of nitrogen and 2 moles of carbon dioxide.

Calculate the values of gamma = C_p//C_v for a gaseous mixture consisting of v_1 = 2.0 moles of oxygen and v_2 = 3.0 mole of carbon dioxide. The gases are assumed to be ideal.

The value of gamma=C_p/C_v for a gaseous mixture consisting of 2.0 moles of oxygen and 3.0 moles of helium. The gases are assumed to be ideal.

The value of gamma=C_p/C_v for a gaseous mixture consisting of 2.0 moles of oxygen and 3.0 moles of helium. The gases are assumed to be ideal.

Calculate the specific heat capacity C_(r) of a gaseous mixture consisting of v_(1) moles of a gas of adiabatic exponent gamma_(1) and v_(2) moles of another gas of adiaqbatic exponent gamma_(2) .

Calculate the specific heat capacity C_(r) of a gaseous mixture consisting of v_(1) moles of a gas of adiabatic exponent gamma_(1) and v_(2) moles of another gas of adiaqbatic exponent gamma_(2) .