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Chemistry Chapter 11

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Chemistry Chapter 11 Molecular Composition of Gases Volume and mass Gay-Lussac examined gas volume in reactions Noted: 2 L H2 and 1 L O2 can form 2 L water vapor 2:1 ... – PowerPoint PPT presentation

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Title: Chemistry Chapter 11


1
Chemistry Chapter 11
  • Molecular Composition of Gases

2
Volume and mass
  • Gay-Lussac examined gas volume in reactions
  • Noted 2 L H2 and 1 L O2 can form 2 L water vapor
  • 212 volume relationship of HO water
  • Simple definite proportions hold true for other
    gases in reactions
  • this lead to .

3
Gay-Lussacs Law of Combining Gas Volumes
  • At constant temperature and pressure the volumes
    of gaseous reactants and products can be
    expressed as ratios of small whole numbers

4
Avogadro (again)
  • Combining volumes seemed to challenge the
    indivisibility of the atom
  • Avogadro posited that some molecules might
    contain more than one atom (ex. O2 explains the
    212 HOwater ratio)
  • Avogadro's Law Equal volumes of gases at the
    same temperature and pressure contain equal
    numbers of molecules

5
Implications of Avogadro
  • At the same temperature and pressure the volume
    of a gas varies directly with the number of
    molecules
  • Avogadro believed that some elements must exist
    in diatomic form (H2, O2, N2)

6
Avogadro continued
  • H, O and water illustrate this well
  • 2 volumes H2 1 volume O2 2 volumes H2O
  • Leads to the balanced equation
  • 2H2 O2 ? 2H2O
  • Which confirms the diatomic molecule hunch nicely!

7
Avogadro in algebra
  • Gas volume is directly proportional to the amount
    of gas (number of particles) at a given
    temperature and pressure give us
  • V kn
  • Where
  • V is volume
  • n is the amount of gas (in moles)
  • k is a constant

8
Molar Volumes
  • One mole of gas at STP will occupy 22.4 L
  • 1 mole/ 22.4 L of ________gas can be used as a
    conversion factor to find number of particles,
    mass, or volume of a gas at STP
  • Practice!
  • Problems 1-3 page 337

9
Ideal Gas Law
11-2
  • A mathematical relationship among pressure,
    volume, temperature and number of moles
  • To derive (see p. 341)
  • Ideal gas law
  • V nRT/P OR PV nRT
  • V is volume, P is pressure, T is temperature, n
    is number of moles, and R is a constant

10
The Ideal Gas Constant
  • R (1 atm) (22.4 L)/(1 mol) (273.15 K)
  • Or
  • R 0.08205784 L x atm / mol x K
  • (round to .0821)
  • USE ONLY when units are appropriate!
  • For any other units see chart on p. 342
  • Practice Problems! p. 345

11
Finding Molar Mass or Density
  • Use V nRT/P but remember that n (number of
    moles) is equal to mass (m) /molar mass (M)
  • Substituting gives
  • PV mRT/M or M mRT/PV
  • Density is just mass (m) per unit volume (V)
  • Substituting gives
  • M DRT/P or D MP/RT
  • Practice problems! 1-4 page 346

12
Stoichiometry of gases
11-3
  • Volume ratios of gases in reactions can be used
    exactly as mole ratios are in standard mass-mole,
    mass-mass, mole mole etc. problems
  • Practice! 1-2 pg. 348

13
More Stoich!
  • When given a volume for a reactant and a mass
    for a reactant
  • Go through moles
  • Need conditions (temp, pressure, etc) for each
    gas
  • Ideal gas law works well for this
  • Practice problems! 1-2, p.349 1-2 p.350

14
Effusion and Diffusion
  • Rates of either can be calculated!
  • Remember! KE ½ m v2
  • And for any two gases (A B, lets say) at the
    same temp KEA KEB so
  • ½ MA vA2 ½ MBvB2
  • Where M is molar mass and v is molecular velocity
  • You can multiply by 2 to clean up and get
  • MA vA2 MBvB2

15
Effusion and diffusion (cont)
  • Recall MA vA2 MB vB2
  • Rearrange vA2 / vB2 MB / MA
  • Take square roots vA / vB vMB / vMA
  • Because rate of effusion is directly proportional
    to molecular velocity we can say that
  • rate of effusionA / rate of effusionB vMB / vMA

16
Grahams Law of effusion
  • Rates of effusion of gases at the same
    temperature and pressure are inversely
    proportional to the square roots of their molar
    masses
  • So? Density varies directly with molar mass so
  • rate of effusionA / rate of effusionB vDB / vDA
  • (Where D is density)

17
Grahams
  • Can be used to find density or molar mass of
    gases effusing.
  • Practice problems! 1-3 p.355

18
Thats all folks!
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