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THE BEHAVIOR OF GASES

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No attractive or repulsive forces exist between particles. ... Can't keep all the laws straight in the ol' noggin? Use the Combined Gas Law: P1V1/T1 = P2V2/T2 ... – PowerPoint PPT presentation

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Title: THE BEHAVIOR OF GASES


1
THE BEHAVIOR OF GASES
  • CHEMISTRY
  • CHAPTER 12

2
Learn The Gas Laws
3
Kinetic Theory Revisited
  • Assumptions
  • 1. Gases consist of hard, spherical particles
  • -Individual volumes of particles are
    insignificant
  • -Considerable empty space between particles
    (gases are compressible)

4
Kinetic Theory Revisited
  • No attractive or repulsive forces exist between
    particles.
  • -Gases are free to move around their containers
  • -Gases take the size and shape of the container

5
Kinetic Theory Revisited
  • Gas particles move rapidly in constant random
    motion.
  • -Particles travel in straight lines
  • -Move independently of each other
  • -When there is a collision, it is perfectly
    elastic.
  • -No loss in kinetic energy, KE is passed from on
    particle to another
  • -KE is directly proportional to the Kelvin
    temperature of the gas

6
Variables to Describe a Gas
  • Pressure (P) in kilopascals
  • Volume (V) in liters
  • Temperature (T) in kelvins
  • Number of moles (n)
  • These will be used in the gas laws learned in
    this chapter of study.

7
Factors Affecting Gas Pressure
  • Amount of Gas
  • -temperature being constant double the number
    of particles and you double the pressure
  • -tripling would triple the pressure
  • -decreasing the number would cause a decrease in
    pressure (adiabatic change)
  • Volume
  • -reduce volume by half doubles pressure
  • -increasing volume has the opposite effect
  • Temperature
  • -if average KE doubles, pressure doubles
  • -as temperature decreases, particles move more
    slowly and have less KE

8
The Gas Laws
  • Boyles Law
  • Charless Law
  • Gay-Lussacs Law
  • Combined Gas Law
  • Ideal Gas Law

9
BOYLES LAW
  • For a given mass of gas at a constant
    temperature, the volume of the gas varies
    inversely with pressure.
  • Mathematically speaking
  • P1V1 P2V2
  • Pressure is always constant at a constant
    temperature.

10
Charless Law
  • The volume of a fixed mass of gas is directly
    proportional to its Kelvin temperature if the
    pressure is kept constant.
  • Mathematically speaking
  • V1/T1 V2/T2
  • Temperature must be in Kelvin.

11
Charless Law
12
Gay-Lussacs Law
  • The pressure of a gas is directly proportional to
    the Kelvin temperature if the volume remains
    constant.
  • Mathematically speaking
  • P1/T1 P2/T2

13
Combined Gas Law
  • Cant keep all the laws straight in the ol
    noggin?
  • Use the Combined Gas Law
  • P1V1/T1 P2V2/T2
  • The previous gas laws can be derived from this
    equation.

14
Ideal Gas Law
  • Along with the prior three variables (pressure,
    temperature, and volume) a fourth needs to be
    considered. The number of moles (n) of a gas in
    a fixed volume at a known temperature and
    pressure.
  • Ideal gas Law
  • P V n R T
  • R Ideal gas constant 8.31 LPa/Kmol

15
Ideal Gas Law and Kinetic Theory
  • The advantage of using the Ideal Gas Law vs the
    Combined Gas Law is that you will be able to
    calculate the number of moles of a gas present if
    you know the other conditions.
  • An important behavior of real gases that differs
    from ideal gases is that a real gas cooled might
    condense to a liquid or solid and thus have a
    volume. Ideal gases would not have a volume at
    this condition.

16
Avogadros Hypothesis
  • Common sense would tell us that large gas
    molecules, like Cl2, would occupy a larger volume
    than a small one, H2.
  • Avogadro proved otherwise!!
  • His hypothesis Equal volumes of gases at the
    same temperature and pressure contain equal
    numbers of particles.
  • At STP One mole (6.02 x 1023) has a volume of
    22.4 liters.

17
Making Sense of Avogadros Constant
  • Particles of gas are far apart with a great deal
    of empty space between them.
  • Equal numbers of particles of different gases in
    equal volumes at the same temperature should
    exert the same pressure due to the particles
    having the same average kinetic energy and the
    same volume to move about so thus, the same
    number of collisions.

18
Daltons Law of Partial Pressures
  • At constant volume and temperature, the total
    pressure exerted by a mixture of gases is equal
    to the sum of the partial pressures of the
    component gases.
  • The contribution each gas makes to the total is
    the partial pressure of that gas.
  • Mathematically speaking
  • Ptotal P1 P2 P3 ..

19
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20
Grahams Law of Diffusion
  • The rate of effusion (diffusion) of a gas is
    inversely proportional to the square root of the
    gass molar mass.
  • Diffusion tendency of molecules to move toward
    areas of lower concentration until the
    concentration is uniform.
  • Effusion the process in which a gas escapes
    through a tiny hole in its container.

21
Grahams Law of Effusion
  • Mathematically speaking
  • RateA/RateB vmolar massB/vmolar massA
  • A helium/air filled balloon is a good example of
    this phenomena. Because helium has a much lower
    mass than nitrogen, it effuses much faster
    through the pores of the balloon.

22
  • This was a gas!!!!
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