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Kinetic Theory of Gases

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Lee Carkner's standard AS311 power point template ... Physics 202 Professor Lee Carkner Lecture 13 What is a Gas? But where do pressure and temperature come from? – PowerPoint PPT presentation

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Title: Kinetic Theory of Gases


1
Kinetic Theory of Gases
  • Physics 202
  • Professor Lee Carkner
  • Lecture 13

2
What is a Gas?
  • But where do pressure and temperature come from?
  • A gas is made up of molecules (or atoms)
  • The pressure is a measure of the force the
    molecules exert when bouncing off a surface
  • We need to know something about the microscopic
    properties of a gas to understand its behavior

3
Mole
  • A gas is composed of molecules
  • m
  • N
  • When thinking about molecules it sometimes is
    helpful to use the mole
  • 1 mol 6.02 X 1023 molecules
  • 6.02 x 1023 is called Avogadros number (NA)
  • M
  • M mNA
  • A mole of any gas occupies about the same volume

4
Ideal Gas
  • Specifically, 1 mole of any gas held at constant
    temperature and constant volume will have almost
    the same pressure
  • Gases that obey this relation are called ideal
    gases
  • A fairly good approximation to real gases

5
Ideal Gas Law
  • The temperature, pressure and volume of an ideal
    gas is given by
  • pV nRT
  • Where
  • R is the gas constant 8.31 J/mol K
  • V in cubic meters

6
Work and the Ideal Gas Law
  • pnRT (1/V)

7
Isothermal Process
  • If we hold the temperature constant in the work
    equation
  • W nRT ln(Vf/Vi)
  • Work for ideal gas in isothermal process

8
Isotherms
  • From the ideal gas law we can get an expression
    for the temperature
  • For an isothermal process temperature is constant
    so
  • If P goes up, V must go down
  • Lines of constant temperature
  • One distinct line for each temperature

9
Constant Volume or Pressure
  • W0
  • W ?pdV p(Vf-Vi)
  • W pDV
  • For situations where T, V or P are not constant,
    we must solve the integral
  • The above equations are not universal

10
Gas Speed
  • The molecules bounce around inside a box and
    exert a pressure on the walls via collisions
  • The pressure is a force and so is related to
    velocity by Newtons second law Fd(mv)/dt
  • The rate of momentum transfer depends on volume
  • The final result is
  • p (nMv2rms)/(3V)
  • Where M is the molar mass (mass of 1 mole)

11
RMS Speed
  • There is a range of velocities given by the
    Maxwellian velocity distribution
  • We take as a typical value the root-mean-squared
    velocity (vrms)
  • We can find an expression for vrms from the
    pressure and ideal gas equations
  • vrms (3RT/M)½
  • For a given type of gas, velocity depends only on
    temperature

12
MaxwellsDistribution
13
Translational Kinetic Energy
  • Using the rms speed yields
  • Kave ½mvrms2
  • Kave (3/2)kT
  • Where k (R/NA) 1.38 X 10-23 J/K and is called
    the Boltzmann constant
  • Temperature is a measure of the average kinetic
    energy of a gas

14
Maxwellian Distribution and the Sun
  • The vrms of protons is not large enough for them
    to combine in hydrogen fusion
  • There are enough protons in the high-speed tail
    of the distribution for fusion to occur

15
Next Time
  • Read 19.8-19.11
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