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Stoichiometry

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... should then be considered in terms of moles: 4 Fe 3 O2 2 Fe2O3 ... 5. Change from moles to the desired unit in the final span of the bridge. Mole Changer ... – PowerPoint PPT presentation

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Title: Stoichiometry


1
Stoichiometry
2
Stoichiometry
  • The study of quantitative relationships between
    amounts of reactants and products. Based on the
    Law of conservation of Massnothing lost or
    gained in a chemical reaction
  • Stoichiometry depends on a balanced chemical
    equation if equation is not written correctly
    and balanced , NOTHING can be determined

3
Interpreting Equations
  • Since molecules and formula units are the basic
    reacting pieces, moles must be used to transfer
    information between reactants and products. The
    balanced equation should then be considered in
    terms of moles
  • 4 Fe 3 O2 ? 2 Fe2O3
  • 4moles 3 moles 2 moles
  • C3H8 5 O2 ? 3 CO2 4 H2O
  • 1 mole 5 moles 3 moles 4 moles

4
Examplesp3561
5
Mole Ratios
  • Every relationship between reactants and products
    can be reduced to a ratio of moles from the
    balanced equation
  • 2 Al 3 Br2 ? 2 AlBr3
  • Ratios can be made for each 3 Br2 or
    2 AlBr3
  • 2 Al 2 Al
  • 2 Al or 2 AlBr3 2
    Al or 3 Br2
  • 3 Br2 3 Br2 2 AlBr3 2
    AlBr3
  • Each will be used when needed to change between
    substances in stoichiometry

6
Examplesp3572
7
Homework 12a
  • p. 357 3
  • p378 ff 51-53, 54, 56, 58, 60

8
Stoichiometric Calculations
  • From moles to molesfollow the ratios
  • 2 K 2 H2O ? 2 KOH H2
  • How many moles H2 from 0.0400 moles K ?
  • 0.0400 moles K 1 mole H2 0.0200
    moles H2
  • 2 moles K
  • moles given mole ratio

9
Examplep 359
10
Moles to Mass
  • Involves one more stepchange moles of product to
    mass using molar mass
  • 2 Na Cl2 ? 2 NaCl
  • What mass of NaCl from 1.25 moles Cl2?

11
Mass to Mass
  • Full Regular stoichiometric calculation involves
    first change given mass to moles, switch
    substances with the mole ratio, then change back
    to mass of new substance with its molar mass.
  • NH4NO3 ? N2O 2 H2O
  • What mass of H2O from 25.0 g NH4NO3 ?

12
Stoichiometry
  • Calculations within reactions-- Bridge Method
  • 1. Find reactants and products and write a
    balanced reaction
  • 2. Place amount of given substance at top left
    of bridge
  • 3. Convert the given to moles if necessary in
    the next span of the bridge
  • 4. Change from moles of given substance to
    moles of desired substance in the nest span,
    using coefficients from the balanced equation
  • 5. Change from moles to the desired unit in the
    final span of the bridge

13
Mole Changer
  • PARTICLES??MOLES??MASS (grams)

14
Examples
  • One way of producing O2(g) involves the
    decomposition of potassium chlorate into
    potassium chloride and oxygen gas. A 25.5 g
    sample of Potassium chlorate is decomposed. How
    many moles of O2(g) are produced?

15
Examples
  • How many grams of each reactant are needed to
    produce 15 grams of iron form the following
    reaction? Fe2O3(s) Al(s) Fe(s) Al2O3(s)

16
Examples
  • K2PtCl4(aq) NH3(aq) Pt(NH3)2Cl2 (s) KCl(aq)
  • what mass of Pt(NH3)2Cl2 can be produced from 65
    g of K2PtCl4 ?
  • How much KCl will be produced?

17
Examples
K2PtCl4(aq) NH3(aq) Pt(NH3)2Cl2 (s)
KCl(aq) How much from 65 grams of NH3?
18
Homework 12b
  • p. 359 10
  • p. 360 12
  • p. 362 13, 14
  • p. 379 ff 62, 64, 72, 74, 75

19
Limiting Reagent
  • Reactant that determines the amount of product
    formed.
  • The one you run out of first.
  • Makes the least product.

20
Limiting Reagent
  • To determine the limiting reagent requires that
    you do two stoichiometry problems.
  • Figure out how much product each reactant makes.
  • The one that makes the least is the limiting
    reagent.

21
Example
  • Ammonia is produced by the following
    reaction N2 H2 NH3
  • What mass of ammonia can be produced from a
    mixture of 100. g N2 and 500. g H2 ?
  • How much unreacted material remains?

22
Excess Reagent / Yield
  • The reactant you dont run out of.
  • The amount of stuff you make is the yield.
  • The theoretical yield is the amount you would
    make if everything went perfect.
  • The actual yield is what you make in the lab.

23
Percent Yield
  • yield Actual x 100
    Theoretical
  • yield what you got x 100
    what you could have got

24
Examples
  • Aluminum burns in bromine producing aluminum
    bromide. In a laboratory 6.0 g of aluminum reacts
    with excess bromine. 50.3 g of aluminum bromide
    are produced. What are the three types of yield.

25
Examples
  • Years of experience have proven that the percent
    yield for the following reaction is 74.3 Hg
    Br2 HgBr2
  • If 10.0 g of Hg and 9.00 g of Br2 are reacted,
    how much HgBr2 will be produced?

26
Examples
Hg Br2 HgBr2 If the reaction did go to
completion, how much excess reagent would be
left? (10.0 g of Hg and 9.00 g of Br2 )
27
Examples
  • Commercial brass is an alloy of Cu and Zn. It
    reacts with HCl by the following reaction
  • Zn(s) 2HCl(aq) ZnCl2 (aq) H2(g) Cu
    does not react. When 0.5065 g of brass is reacted
    with excess HCl, 0.0985 g of ZnCl2 are eventually
    isolated. What is the composition of the brass?

28
Homework 12c
  • p. 368 20
  • p. 372 28
  • p. 380ff 78, 82, 84, 87
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