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2.S: The Kinetic Theory of Gases (Summary)

  • Page ID
    10271
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    Key Terms

    Avogadro’s number \(N_A\), the number of molecules in one mole of a substance; \(N_A=6.02×10^{23}\) particles/mole
    Boltzmann constant \(k_B\), a physical constant that relates energy to temperature and appears in the ideal gas law; \(k_B=1.38×10^{−23}J/K\)
    critical temperature \(T_c\) at which the isotherm has a point with zero slope
    Dalton’s law of partial pressures physical law that states that the total pressure of a gas is the sum of partial pressures of the component gases

    degree o+f freedom

    independent kind of motion possessing energy, such as the kinetic energy of motion in one of the three orthogonal spatial directions
    equipartition theorem theorem that the energy of a classical thermodynamic system is shared equally among its degrees of freedom
    ideal gas gas at the limit of low density and high temperature
    ideal gas law physical law that relates the pressure and volume of a gas, far from liquefaction, to the number of gas molecules or number of moles of gas and the temperature of the gas
    internal energy sum of the mechanical energies of all of the molecules in it
    kinetic theory of gases theory that derives the macroscopic properties of gases from the motion of the molecules they consist of
    Maxwell-Boltzmann distribution function that can be integrated to give the probability of finding ideal gas molecules with speeds in the range between the limits of integration
    mean free path average distance between collisions of a particle
    mean free time average time between collisions of a particle
    mole quantity of a substance whose mass (in grams) is equal to its molecular mass
    most probable speed speed near which the speeds of most molecules are found, the peak of the speed distribution function
    partial pressure pressure a gas would create if it occupied the total volume of space available
    peak speed same as “most probable speed”
    pV diagram graph of pressure vs. volume
    root-mean-square (rms) speed square root of the average of the square (of a quantity)
    supercritical condition of a fluid being at such a high temperature and pressure that the liquid phase cannot exist
    universal gas constant R, the constant that appears in the ideal gas law expressed in terms of moles, given by \(R=N_Ak_B\)
    van der Waals equation of state equation, typically approximate, which relates the pressure and volume of a gas to the number of gas molecules or number of moles of gas and the temperature of the gas
    vapor pressure partial pressure of a vapor at which it is in equilibrium with the liquid (or solid, in the case of sublimation) phase of the same substance

    Key Equations

    Ideal gas law in terms of molecules \(pV=Nk_BT\)
    Ideal gas law ratios if the amount of gas is constant \(\frac{p_1V_1}{T_1}=\frac{p_2V_2}{T_2}\)
    Ideal gas law in terms of moles \(pV=nRT\)
    Van der Waals equation \([p+a(\frac{n}{V})^2](V−nb)=nRT\)
    Pressure, volume, and molecular speed \(pV=\frac{​1}{3}Nm\bar{v^2}\)
    Root-mean-square speed \(v_{rms}=\sqrt{\frac{3RT}{M}}=\sqrt{\frac{3k_BT}{m}}\)
    Mean free path \(λ=\frac{V}{4\sqrt{2}πr^2N}=\frac{k_BT}{4\sqrt{2}πr^2}\)
    Mean free time \(τ=\frac{k_BT}{4\sqrt{2}πr^2pv_{rms}}\)

    The following two equations apply only to a monatomic ideal gas:

    Average kinetic energy of a molecule \(\bar{K}=\frac{3}{2}k_BT\)
    Internal energy \(E_{int}=\frac{3}{2}Nk_BT\).
    Heat in terms of molar heat capacity at constant volume \(Q=nCVΔT\)
    Molar heat capacity at constant volume for an ideal gas with d degrees of freedom \(C_V=\frac{d}{2}R\)
    Maxwell–Boltzmann speed distribution \(f(v)=\frac{4}{\sqrt{π}}(\frac{m}{2k_BT})^{3/2}v^2e^{−mv^2/2k_BT}\)
    Average velocity of a molecule \(\bar{v}=\sqrt{\frac{8}{π}\frac{k_BT}{m}}=\sqrt{\frac{8}{π}\frac{RT}{M}}\)
    Peak velocity of a molecule \(v_p=\sqrt{\frac{2k_BT}{m}}=\sqrt{\frac{2RT}{M}}\)

    Summary

    2.2 Molecular Model of an Ideal Gas

    • The ideal gas law relates the pressure and volume of a gas to the number of gas molecules and the temperature of the gas.
    • A mole of any substance has a number of molecules equal to the number of atoms in a 12-g sample of carbon-12. The number of molecules in a mole is called Avogadro’s number \(N_A\),

    \(N_A=6.02×10^{23}mol^{−1}\).

    • A mole of any substance has a mass in grams numerically equal to its molecular mass in unified mass units, which can be determined from the periodic table of elements. The ideal gas law can also be written and solved in terms of the number of moles of gas:

    \(pV=nRT\),

    where n is the number of moles and R is the universal gas constant,

    \(R=8.31J/mol⋅K\).

    • The ideal gas law is generally valid at temperatures well above the boiling temperature.
    • The van der Waals equation of state for gases is valid closer to the boiling point than the ideal gas law.
    • Above the critical temperature and pressure for a given substance, the liquid phase does not exist, and the sample is “supercritical.”

    2.3 Pressure, Temperature, and RMS Speed

    • Kinetic theory is the atomic description of gases as well as liquids and solids. It models the properties of matter in terms of continuous random motion of molecules.
    • The ideal gas law can be expressed in terms of the mass of the gas’s molecules and \(\bar{v^2}\), the average of the molecular speed squared, instead of the temperature.
    • The temperature of gases is proportional to the average translational kinetic energy of molecules. Hence, the typical speed of gas molecules \(v_{rms}\) is proportional to the square root of the temperature and inversely proportional to the square root of the molecular mass.
    • In a mixture of gases, each gas exerts a pressure equal to the total pressure times the fraction of the mixture that the gas makes up.
    • The mean free path (the average distance between collisions) and the mean free time of gas molecules are proportional to the temperature and inversely proportional to the molar density and the molecules’ cross-sectional area.

    2.4 Heat Capacity and Equipartition of Energy

    • Every degree of freedom of an ideal gas contributes \(\frac{1}{2}k_BT\) per atom or molecule to its changes in internal energy.
    • Every degree of freedom contributes \(\frac{1}{2}R\) to its molar heat capacity at constant volume \(C_V\).
    • Degrees of freedom do not contribute if the temperature is too low to excite the minimum energy of the degree of freedom as given by quantum mechanics. Therefore, at ordinary temperatures, d=3 for monatomic gases, d=5 for diatomic gases, and d≈6 for polyatomic gases.

    2.5 Distribution of Molecular Speeds

    • The motion of individual molecules in a gas is random in magnitude and direction. However, a gas of many molecules has a predictable distribution of molecular speeds, known as the Maxwell-Boltzmann distribution.
    • The average and most probable velocities of molecules having the Maxwell-Boltzmann speed distribution, as well as the rms velocity, can be calculated from the temperature and molecular mass.

    Contributors and Attributions

    Samuel J. Ling (Truman State University), Jeff Sanny (Loyola Marymount University), and Bill Moebs with many contributing authors. This work is licensed by OpenStax University Physics under a Creative Commons Attribution License (by 4.0).


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