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The Kinetic Molecular Theory

The Kinetic Molecular Theory. Kinetic Molecular Theory. We have been using an equation entitled the “ideal” gas law. What is an “ideal” gas??. Kinetic Molecular Theory. No gas is ideal! But, many gases come close to ideal under certain conditions. Kinetic Molecular Theory.

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The Kinetic Molecular Theory

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  1. The Kinetic Molecular Theory

  2. Kinetic Molecular Theory • We have been using an equation entitled the “ideal” gas law. • What is an “ideal” gas??

  3. Kinetic Molecular Theory • No gas is ideal! • But, many gases come close to ideal under certain conditions

  4. Kinetic Molecular Theory • The Kinetic Molecular Theory of Gases attempts to define what an “ideal” gas is.

  5. Kinetic Molecular Theory • 1. The particles are so small compared with the distances between them, that the volume of the individual particles can be assumed to be zero.

  6. Kinetic Molecular Theory • 2. The particles are in constant motion. The collisions of the particles with the walls of the container are the cause of pressure exerted by gas.

  7. Kinetic Molecular Theory • 3.The particles are assumed to exert no forces on each other; they are assumed to neither to attract or repel each other.

  8. Kinetic Molecular Theory • 4. The average kinetic energy of a collection of gas particles is assumed to be directly proportional to the Kelvin temp of the gas.

  9. Real Gases • Real gas particles do have finite volumes and do exert forces. • Ideal behavior is what is approached by gases.

  10. Deviations • When P is plotted vs. PV/nRT there is some deviation from an ideal gas. • What pressure is “most ideal”?

  11. Deviations • When P is plotted vs. PV/nRT at different temps, which temp is closest to “ideal”

  12. Where is it best? • The ideal gas law works best at LOW pressure and HIGH temperatures. • Why?

  13. Correction Factors • Van der Waals developed an equation for real gases in 1873. • He corrected for the “ideal” gas assumptions.

  14. Correction Factors • 1. Corrected for the volume by subtracting the volume of the molecules. nb

  15. Correction Factors • 2. Accounted for the interactions by adding a “correction factor” that would help make the pressure higher.

  16. Correction Factors • The size of the pressure correction factor depends on the number of particles present (represented as moles/L)

  17. So... • Why high temps and low pressure??? • High temps- less time to interact

  18. So... • Low pressure- take up less of available space

  19. Effusion and Diffusion

  20. Effusion • The passing of a gas through a tiny hole into an empty chamber

  21. Graham’s Law • Found that the rate of effusion of a gas is inversely proportional to the square root of the mass of its particles

  22. Diffusion • The mixing of gases

  23. RMS Velocity • The root mean square velocity is an average velocity that we can find for particles

  24. μRMS = (3RT/M)1/2 • The constants are: • R = 8.31 J/mol K • T = temp in Kelvin • M = mass of mole of gas in KILOGRAMS!

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