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Limiting Reagents and Percent Yield

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Title: Limiting Reagents and Percent Yield


1
Limiting Reagents and Percent Yield
2
What Is a Limiting Reagent?
  • Many cooks follow a recipe when making a new
    dish.
  • When a cook prepares to cook he/she needs to know
    that sufficient amounts of all the ingredients
    are available.
  • Lets look at a recipe for the formation of a
    double cheeseburger

3
1 hamburger bun
1 tomato slice
1 lettuce leaf
2 slices of cheese
2 burger patties
4
  • If you want to make 5 double cheese burgers
  • How many hamburger buns do you need?

5
  • How many hamburger patties do you need?

10
  • How many slices of cheese do you need?

10
  • How many slices of tomato do you need?

5
5
  • How many double cheeseburgers can you make if you
    start with
  • 1 bun, 2 patties, 2 slices of cheese, 1 tomato
    slice

1
  • 2 buns, 4 patties, 4 slices of cheese, 2 tomato
    slices

2
  • 1 mole of buns, 2 moles of patties, 2 moles of
    cheese, 1 mole of tomato slices

1 mole
  • 10 buns, 20 patties, 2 slices of cheese, 10
    tomato slices

1
6
  • We cant make anymore than 1 double cheeseburger
    with our ingredients.
  • The slices of cheese limits the number of
    cheeseburgers we can make.
  • If one of our ingredients gets used up during our
    preparation it is called the limiting reactant
    (LR)
  • The LR limits the amount of product we can form
    in this case double cheeseburgers.
  • It is equally impossible for a chemist to make a
    certain amount of a desired compound if there
    isnt enough of one of the reactants.

7
  • As weve been learning, a balanced chemical rxn
    is a chemists recipe.
  • Which allows the chemist to predict the amount of
    product formed from the amounts of ingredients
    available
  • Lets look at the reaction equation for the
    formation of ammonia

N2(g) 3H2(g) ? 2NH3(g)
  • When 1 mole of N2 reacts with 3 moles of H2, 2
    moles of NH3 are produced.
  • How much NH3 could be made if 2 moles of N2 were
    reacted with 3 moles of H2?

2 mols of ammonia
8
N2(g) 3H2(g) ? 2NH3(g)
  • The amount of H2 limits the amount of NH3 that
    can be made.
  • From the amount of N2 available we can make 4
    moles of NH3
  • From the amount of H2 available we can only make
    2 moles of NH3.
  • H2 is our limiting reactant here.
  • It runs out before the N2 is used up.
  • Therefore, at the end of the reaction there
    should be N2 left over.
  • When there is reactant left over it is said to be
    in excess.

9
  • How much N2 will be left over after the reaction?
  • In our rxn it takes 1 mol of N2 to react all of 3
    mols of H2, so there must be 1 mol of N2 that
    remains unreacted.
  • We can use our new stoich calculation skills to
    determine 3 possible types of LR type
    calculations.
  • Determine which of the reactants will run out
    first (limiting reactant)
  • Determine amount of product
  • Determine how much excess reactant is wasted

10
Limiting Reactant Problems
Given the following reaction 2Cu S ? Cu2S
  • What is the limiting reactant when 82.0 g of Cu
    reacts with 25.0 g S?
  • What is the maximum amount of Cu2S that can be
    formed?
  • How much of the other reactant is wasted?

11
  • Our 1st goal is to calculate how much S would
    react if all of the Cu was reacted.
  • From that we can determine the limiting reactant
    (LR).
  • Then we can use the Limiting Reactant to
    calculate the amount of product formed and the
    amount of excess reactant left over.

82g Cu?
mol Cu?
mol S?
g S
12
2Cu S ? Cu2S
1mol S
1molCu
32.1g S
82.0gCu
2molCu
1mol S
63.5gCu
20.7 g S
  • So if all of our 82.0g of Copper were reacted
    completely it would require only 20.7 grams of
    Sulfur.
  • Since we initially had 25g of S, we are going to
    run out of the Cu, the limiting reactant) end
    up with 4.3 grams of S

13
  • Copper being our Limiting Reactant is then used
    to determine how much product is produced.
  • The amount of Copper we initially start with
    limits the amount of product we can make.

1molCu2S
1molCu
159gCu2S
82.0gCu
2molCu2S
1molCu2S
63.5gCu
103 g Cu2S
14
  • So the reaction between 82.0g of Cu and 25.0g of
    S can only produce 103g of Cu2S.
  • The Cu runs out before the S and we will end up
    wasting 4.7 g of the S.

Ex 2 Hydrogen gas can be produced in the lab by
the rxn of Magnesium metal with HCl according to
the following rxn equation Mg 2HCl ? MgCl2
H2
  • What is the LR when 6.0 g HCl reacts with 5.0 g
    Mg? What is the maximum amount of H2 that can be
    formed? And how much of the other reactant is
    wasted?

15
5.0g Mg ?
mol Mg ?
2mol HCl ?
g HCl
36.5gHCl
1molMg
2molHCl
5.0g Mg
1molHCl
1molMg
24.3gMg
15.0g HCl
  • So if 5.0g of Mg were used up it would take 15.0g
    HCl, but we only had 6.0g of HCl to begin with.
  • Therefore, the 6.0g of HCl will run out before
    the 5.0g of Mg, so HCl is our Limiting Reactant.

16
6.0g HCl?
2mol HCl ?
1mol H2 ?
g H2
2.0gH2
1molHCl
1molH2
6.0g HCl
1molH2
2molHCl
36.5gHCl
0.164 g H2 produced
6.0g HCl?
2mol HCl ?
1mol Mg ?
g Mg
24.3gMg
1molHCl
1molMg
6.0g HCl
1molMg
2molHCl
36.5gHCl
1.997 g Mg
- 5.0 g Mg
3.01g Mg extra
17
Calculating Percent Yield
  • In theory, when a teacher gives an exam to the
    class, every student should get a grade of 100.
  • Your exam grade, expressed as a perc-ent, is a
    quantity that shows how well you did on the exam
    compared with how well you could have done if you
    had answered all questions correctly

18
  • This calc is similar to the percent yield calc
    that you do in the lab when the product from a
    chemical rxn is less than you expected based on
    the balanced eqn.
  • You might have assumed that if we use stoich to
    calculate that our rxn will produce 5.2 g of
    product, that we will actually recover 5.2 g of
    product in the lab.
  • This assumption is as faulty as assuming that all
    students will score 100 on an exam.

19
  • When an equation is used to calculate the amount
    of product that is possible during a rxn, a value
    representing the theoretical yield is obtained.
  • The theoretical yield is the maximum amount of
    product that could be formed from given amounts
    of reactants.
  • In contrast, the amount of product that forms
    when the rxn is carried out in the lab is called
    the actual yield.
  • The actual yield is often less than the
    theoretical yield.

20
  • The percent yield is the ratio of the actual
    yield to the theoretical yield as a percent
  • It measures the measures the efficiency of the
    reaction

actual yield
Percent yield
x 100
theoretical yield
  • What causes a percent yield to be less than 100?

21
  • Rxns dont always go to completion when this
    occurs, less than the expected amnt of product is
    formed.
  • Impure reactants and competing side rxns may
    cause unwanted products to form.
  • Actual yield can also be lower than the
    theoretical yield due to a loss of product during
    filtration or transferring between containers.
  • If a wet precipitate is recovered it might weigh
    heavy due to incomplete drying, etc.

22
Calcium carbonate is synthesized by heating,as
shown in the following equation CaO CO2 ?
CaCO3
  • What is the theoretical yield of CaCO3 if 24.8 g
    of CaO is heated with 43.0 g of CO2?
  • What is the percent yield if 33.1 g of CaCO3 is
    produced?

Determine which reactant is the limiting and
then decide what the theoretical yield is.
23
24.8gCaO?
molCaO?
mol CO2?
gCO2
24.8 g CaO
1molCaO
1mol CO2
44 g CO2
56g CaO
1mol CaO
1molCO2
LR
19.5gCO2
1mol CaO
100g CaCO3
24.8 g CaO
1molCaCO3
56g CaO
1mol CaO
1molCaCO3
44.3 g CaCO3
24
  • CaO is our LR, so the reaction should
    theoretically produce 44.3 g of CaCO3 (How
    efficient were we?)
  • Our percent yield is

33.1 g CaCO3
Percent yield
x 100
44.3 g CaCO3
Percent yield 74.7
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