The molar mass of an ideal gas can be calculated from the expression

The rms speed at NTP of a gas can be calculated from the expression:

The pressure volume work for an ideal gas can be calculated by using the expression w=-int_(V_(i))^(v_(f))Pex dV . The work can also be calculated from the pV-plot by using the area under the curve within the specified limits. When an ideal gas is compressed (a) reversibly or (B) irreversibly from volume V_(i) to V_(f) choose the correct option.

The pressure-volume work for an ideal gas can be calculated by using the expression W=-int_(V_(i))^(V_(f))P_(ex)dV. The work can also be calculated from the pV - plot by using the area under the curve within the specified limits. When an ideal gas is compressed (i) reversibly or (ii) irreversibly from volume V_(i) to V_(f) . Choose the correct option.

The molar heat capacity for an ideal gas

An ideal gas can never be liquefied because .

The order of a reaction underline("can be") calculated from law of mass action.

If C_(p) and C_(v) denote the specific heats (per unit mass of an ideal gas of molecular weight M ), then where R is the molar gas constant.

If 3 moles of H_(2) gas is mixed with 2 moles of helium gas, then calculate equivalent molar mass of the gas and adiabatic exponent of the mixture?