Title: STOICHIOMETRY TUTORIAL
1STOICHIOMETRY TUTORIAL
2Instructions This is a work along tutorial.
Each time you click the mouse or touch the space
bar on your computer, one step of the problem
solving occurs. Pressing the PAGE UP key will
backup the steps.
Get a pencil and paper, a periodic table and a
calculator, and lets get to work.
3(1-2-3) General Approach For Problem Solving
1. Clearly identify the Goal or Goals and the
UNITS involved. (What are you trying to do?)
2. Determine what is given and the UNITS.
3. Use conversion factors (which are really
ratios) and their UNITS to CONVERT what is given
into what is desired.
4Table of Contents Click on each tab to view
problem types.
View Complete Slide Show
Sample problem 1
Sample problem 2
Converting grams to moles
Mole to Mole Conversions
Gram-Mole and Gram-Gram Problems
Solution Stoichiometry Problems
Limiting/Excess/ Reactant and Theoretical Yield
Problems
5Sample problem for general problem solving.
Sam has entered into a 10 mile marathon. Use ALL
of the following conversions (ratios) to
determine how many inches there are in the
race. 5280 ft 1 mile 12 inches 1 ft
1. What is the goal and what units are needed?
Goal ______ inches
2. What is given and its units?
10 miles
Units match
3. Convert using factors (ratios).
10 miles
inches
633600
Goal
Given
Convert
Menu
6Sample problem 2 on problem solving.
A car is traveling at a speed of 45 miles per hr
(45 miles/hr). Determine its speed in kilometers
per second using the following conversion factors
(ratios). 1 mile 5280 ft 1 ft 12 in 1 inch
2.54 cm k 1 x 103 c 1 x 10-2 1 hr 60
min 1 min 60 s
Goal
Given
km s
0.020
This is the same as putting k over k
c cancels c m remains
Units Match!
7Converting grams to moles.
Determine how many moles there are in 5.17 grams
of Fe(C5H5)2.
Goal
Given
units match
5.17 g Fe(C5H5)2
moles Fe(C5H5)2
0.0278
Use the molar mass to convert grams to moles.
Fe(C5H5)2
2 x 5 x 1.001 10.01
2 x 5 x 12.011 120.11
1 x 55.85 55.85
8Stoichiometry (more working with ratios)
Ratios are found within a chemical equation.
2HCl Ba(OH)2 ? 2H2O BaCl2
1
1
coefficients give MOLAR RATIOS
2 moles of HCl react with 1 mole of Ba(OH)2 to
form 2 moles of H2O and 1 mole of BaCl2
9Mole Mole Conversions
When N2O5 is heated, it decomposes
2N2O5(g) ? 4NO2(g) O2(g)
a. How many moles of NO2 can be produced from 4.3
moles of N2O5?
2N2O5(g) ? 4NO2(g) O2(g)
4.3 mol
? mol
Units match
4.3 mol N2O5
moles NO2
8.6
b. How many moles of O2 can be produced from 4.3
moles of N2O5?
2N2O5(g) ? 4NO2(g) O2(g)
4.3 mol
? mol
4.3 mol N2O5
mole O2
2.2
10gram ? mole and gram ? gram conversions
When N2O5 is heated, it decomposes
2N2O5(g) ? 4NO2(g) O2(g)
a. How many moles of N2O5 were used if 210g of
NO2 were produced?
2N2O5(g) ? 4NO2(g) O2(g)
210g
? moles
Units match
210 g NO2
moles N2O5
2.28
b. How many grams of N2O5 are needed to produce
75.0 grams of O2?
2N2O5(g) ? 4NO2(g) O2(g)
75.0 g
? grams
75.0 g O2
grams N2O5
506
11Gram to Gram Conversions
Aluminum is an active metal that when placed in
hydrochloric acid produces hydrogen gas and
aluminum chloride. How many grams of aluminum
chloride can be produced when 3.45 grams of
aluminum are reacted with an excess of
hydrochloric acid?
Al(s) HCl(aq) ? AlCl3(aq)
H2(g)
2 6 2
3
First write a balanced equation.
12Gram to Gram Conversions
Aluminum is an active metal that when placed in
hydrochloric acid produces hydrogen gas and
aluminum chloride. How many grams of aluminum
chloride can be produced when 3.45 grams of
aluminum are reacted with an excess of
hydrochloric acid?
Al(s) HCl(aq) ? AlCl3(aq)
H2(g)
2 6 2
3
? grams
3.45 g
Now lets get organized. Write the information
below the substances.
13gram to gram conversions
Aluminum is an active metal that when placed in
hydrochloric acid produces hydrogen gas and
aluminum chloride. How many grams of aluminum
chloride can be produced when 3.45 grams of
aluminum are reacted with an excess of
hydrochloric acid?
Al(s) HCl(aq) ? AlCl3(aq)
H2(g)
2 6 2
3
? grams
3.45 g
Units match
3.45 g Al
g AlCl3
17.0
Lets work the problem.
We must always convert to moles.
Now use the molar ratio.
Now use the molar mass to convert to grams.
14Molarity
Molarity is a term used to express concentration.
The units of molarity are moles per liter (It is
abbreviated as a capital M)
When working problems, it is a good idea to
change M into its units.
15Solutions
A solution is prepared by dissolving 3.73 grams
of AlCl3 in water to form 200.0 mL solution. A
10.0 mL portion of the solution is then used to
prepare 100.0 mL of solution. Determine the
molarity of the final solution.
What type of problem(s) is this?
Molarity followed by dilution.
16Solutions
A solution is prepared by dissolving 3.73 grams
of AlCl3 in water to form 200.0 mL solution. A
10.0 mL portion of the solution is then used to
prepare 100.0 mL of solution. Determine the
molarity of the final solution.
1st
3.73 g
mol L
0.140
200.0 x 10-3 L
molar mass of AlCl3
dilution formula
M1V1 M2V2
2nd
(0.140 M)(10.0 mL) (? M)(100.0 mL)
final concentration
0.0140 M M2
17Solution Stoichiometry
50.0 mL of 6.0 M H2SO4 (battery acid) were
spilled and solid NaHCO3 (baking soda) is to be
used to neutralize the acid. How many grams of
NaHCO3 must be used?
H2SO4(aq) 2NaHCO3 ? 2H2O(l) Na2SO4(aq)
2CO2(g)
18Solution Stoichiometry
50.0 mL of 6.0 M H2SO4 (battery acid) were
spilled and solid NaHCO3 (baking soda) is to be
used to neutralize the acid. How many grams of
NaHCO3 must be used?
H2SO4(aq) 2NaHCO3 ? 2H2O(l) Na2SO4(aq)
2CO2(g)
50.0 mL
? g
Our Goal
6.0 M
Look! A conversion factor!
19Solution Stoichiometry
50.0 mL of 6.0 M H2SO4 (battery acid) were
spilled and solid NaHCO3 (baking soda) is to be
used to neutralize the acid. How many grams of
NaHCO3 must be used?
H2SO4(aq) 2NaHCO3 ? 2H2O(l) Na2SO4(aq)
2CO2(g)
50.0 mL
? g
Our Goal
6.0 M
NaHCO3 2 mol
H2SO4 50.0 mL
NaHCO3 84.0 g
50.4
g NaHCO3
mol NaHCO3
1 mol H2SO4
20 Solution Stoichiometry
Determine how many mL of 0.102 M NaOH solution
are needed to neutralize 35.0 mL of 0.125 M H2SO4
solution.
2 1
2 1
____NaOH ____H2SO4 ? ____H2O
____Na2SO4
First write a balanced Equation.
21Solution Stoichiometry
Determine how many mL of 0.102 M NaOH solution is
needed to neutralize 35.0 mL of 0.125 M H2SO4
solution.
2 1
2 1
____NaOH ____H2SO4 ? ____H2O
____Na2SO4
0.102 M
35.0 mL
? mL
Our Goal
Since 1 L 1000 mL, we can use this to save on
the number of conversions
Now, lets get organized. Place numerical
Information and accompanying UNITS below each
compound.
22Solution Stoichiometry
Determine how many mL of 0.102 M NaOH solution is
needed to neutralize 35.0 mL of 0.125 M H2SO4
solution.
2 1
2 1
____NaOH ____H2SO4 ? ____H2O
____Na2SO4
0.102 M
35.0 mL
? mL
Units Match
shortcut
H2SO4 35.0 mL
H2SO4 0.125 mol 1000 mL
H2SO4
NaOH 2 mol 1 mol H2SO4
1000 mL NaOH 0.102 mol NaOH
mL NaOH
85.8
Now lets get to work converting.
23Solution Stoichiometry
What volume of 0.40 M HCl solution is needed to
completely neutralize 47.1 mL of 0.75 M Ba(OH)2?
1st write out a balanced chemical equation
24Solution Stoichiometry
What volume of 0.40 M HCl solution is needed to
completely neutralize 47.1 mL of 0.75 M Ba(OH)2?
2HCl(aq) Ba(OH)2(aq) ? 2H2O(l)
BaCl2
47.1 mL 0.75 M
0.40 M
? mL
Units match
HCl 2 mol
Ba(OH)2 47.1 mL
HCl 1000 mL
176
mL HCl
0.40 mol HCl
1 mol Ba(OH)2
25Solution Stochiometry Problem
A chemist performed a titration to standardize a
barium hydroxide solution. If it took 23.28 mL
of 0.135 M hydrochloric acid to neutralize 25.00
mL of the barium hydroxide solution, what was the
concentration of the barium hydroxide solution in
moles per liter (M)?
2 1
2 1
____HCl(aq) ____Ba(OH)2(aq) ?
____H2O(l) ____BaCl2(aq)
25.00 mL
23.28 mL
? mol L
0.135 mol L
First write a balanced chemical reaction.
26Solution Stochiometry Problem
A chemist performed a titration to standardize a
barium hydroxide solution. If it took 23.28 mL
of 0.135 M hydrochloric acid to neutralize 25.00
mL of the barium hydroxide solution, what was the
concentration of the barium hydroxide solution in
moles per liter (M)?
2 1
2 1
____HCl(aq) ____Ba(OH)2(aq) ?
____H2O(l) ____BaCl2(aq)
25.00 mL
23.28 mL
Units match on top!
? mol L
0.135 mol L
mol Ba(OH)2 L
Ba(OH)2
0.0629
25.00 x 10-3 L Ba(OH)2
Units Already Match on Bottom!
27Solution Stochiometry Problem
48.0 mL of Ca(OH)2 solution was titrated with
19.2 mL of 0.385 M HNO3. Determine the molarity
of the Ca(OH)2 solution.
We must first write a balanced equation.
28Solution Stochiometry Problem
48.0 mL of Ca(OH)2 solution was titrated with
19.2 mL of 0.385 M HNO3. Determine the molarity
of the Ca(OH)2 solution.
Ca(OH)2(aq) HNO3(aq) ?
H2O(l)
2
Ca(NO3)2(aq)
2
48.0 mL
19.2 mL
? M
0.385 M
HNO3
19.2 mL
mol(Ca(OH)2) L (Ca(OH)2)
0.0770
48.0 x 10-3L
units match!
29Limiting/Excess/ Reactant and Theoretical Yield
Problems
Potassium superoxide, KO2, is used in rebreathing
gas masks to generate oxygen.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
a. How many moles of O2 can be produced from
0.15 mol KO2 and 0.10 mol H2O?
b. Determine the limiting reactant.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
First copy down the the BALANCED equation!
Now place numerical the information below the
compounds.
30Limiting/Excess/ Reactant and Theoretical Yield
Problems
Potassium superoxide, KO2, is used in rebreathing
gas masks to generate oxygen.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
a. How many moles of O2 can be produced from
0.15 mol KO2 and 0.10 mol H2O?
b. Determine the limiting reactant.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
0.15 mol
? moles
0.10 mol
Hide one
Two starting amounts? Where do we start?
31Limiting/Excess/ Reactant and Theoretical Yield
Problems
Potassium superoxide, KO2, is used in rebreathing
gas masks to generate oxygen.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
a. How many moles of O2 can be produced from
0.15 mol KO2 and 0.10 mol H2O?
b. Determine the limiting reactant.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
0.15 mol
? moles
0.10 mol
Hide
Based on KO2
0.15 mol KO2
mol O2
0.1125
32Limiting/Excess/ Reactant and Theoretical Yield
Problems
Potassium superoxide, KO2, is used in rebreathing
gas masks to generate oxygen.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
a. How many moles of O2 can be produced from
0.15 mol KO2 and 0.10 mol H2O?
b. Determine the limiting reactant.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
0.15 mol
? moles
0.10 mol
Hide
Based on KO2
0.15 mol KO2
mol O2
0.1125
0.10 mol H2O
Based on H2O
mol O2
0.150
33Limiting/Excess/ Reactant and Theoretical Yield
Problems
Potassium superoxide, KO2, is used in rebreathing
gas masks to generate oxygen.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
a. How many moles of O2 can be produced from
0.15 mol KO2 and 0.10 mol H2O?
Determine the limiting reactant.
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
0.15 mol
? moles
0.10 mol
Based on KO2
0.15 mol KO2
mol O2
0.1125
It was limited by the amount of KO2.
0.10 mol H2O
Based on H2O
mol O2
0.150
H2O excess (XS) reactant!
What is the theoretical yield? Hint Which is
the smallest amount? The is based upon the
limiting reactant?
34Theoretical yield vs. Actual yield
Suppose the theoretical yield for an experiment
was calculated to be 19.5 grams, and the
experiment was performed, but only 12.3 grams of
product were recovered. Determine the yield.
Theoretical yield 19.5 g based on limiting
reactant
Actual yield 12.3 g experimentally recovered
35Limiting/Excess Reactant Problem with Yield
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
If a reaction vessel contains 120.0 g of KO2 and
47.0 g of H2O, how many grams of O2 can be
produced?
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
? g
120.0 g
47.0 g
Hide one
120.0 g KO2
Based on KO2
g O2
40.51
36Limiting/Excess Reactant Problem with Yield
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
If a reaction vessel contains 120.0 g of KO2 and
47.0 g of H2O, how many grams of O2 can be
produced?
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
? g
120.0 g
47.0 g
Hide
Based on KO2
120.0 g KO2
g O2
40.51
47.0 g H2O
Based on H2O
g O2
125.3
Question if only 35.2 g of O2 were recovered,
what was the percent yield?
37If a reaction vessel contains 120.0 g of KO2 and
47.0 g of H2O, how many grams of O2 can be
produced?
4KO2(s) 2H2O(l) ? 4KOH(s) 3O2(g)
? g
120.0 g
47.0 g
120.0 g KO2
Based on KO2
g O2
40.51
47.0 g H2O
Based on H2O
g O2
125.3
Determine how many grams of Water were left over.
The Difference between the above amounts is
directly RELATED to the XS H2O.
125.3 - 40.51 84.79 g of O2 that could have
been formed from the XS water.
84.79 g O2
31.83
g XS H2O
38Try this problem (then check your answer)
Calculate the molarity of a solution prepared by
dissolving 25.6 grams of Al(NO3)3 in 455 mL of
solution.
After you have worked the problem, click here to
see setup answer
39Chemistry Stoichiometry Unifying Theme
Constancy, Change, and Measurement Why What How
Enduring Understandings Essential Questions Major Indicators, Prioritized Assessment Examples
The mole is basic unit of measurement in chemistry contains 6.02 x 1023 particles. The mole is the bridge between microscopic and macroscopic world and is used in unit analysis. Stoichiometry is used to predict quantities in chemical reactions. Products are limited by the amount of reactants such as natural resources and the limitation can be predicted. Mass of 1 mole substance can be determined based on the atomic mass in the Periodic Table. How is the mole used in chemical calculations? How is quantity of materials predicted in a chemical reaction? How do available materials limit the amount of products? How is molar mass calculated Essential HS4.4.5.1 use the coefficients of a balanced equation to predict amounts of reactants and products. HS4.4.5 demonstrate that adjusting quantities of reactants will affect the amounts of products formed. HS4.4.A.A identify and define Avogadros number and the mole concept operationally and conceptually. HS4.4.A.B utilize dimensional analysis to perform mole to mole, mass to mass, particle to mole, and mole to particle calculations. HS4.4.A.D use formula mass to calculate percent composition of a compound. HS.4.4A.F solve problems involving quantitative relationships in equations including stoichiometric concepts of mole to mole, particle to particle, mass to mass, mole to volume and volume to mole. HS4.4.A.G manipulate the limiting reagent concept qualitatively to conclude that the starting materials of the chemical industry such as petroleum, are limited resources and decisions must be made about their wise consumption. HS1.6.4 manipulate quantities and/or numerical values in algebraic equations. HS1.7.4 recognize mathematics as an integral part of the scientific process. HS4.4.1.5 calculate the molecular weight of a compound given in the Periodic Table. Pre-assessment Brainstorm the collective terms such as dozen, pairs, gross, etc, and conversions between the terms and their numerical values. Formative Assessment Develop a creative concept map to illustrate the relationships among mole, mass, volume and number of particles. Summative Assessment Competition Students are given a specific amount of iron filing and copper sulfate. They are required to return exact one gram of elemental copper after the reaction is completed. Write an article for your school paper about the air pollution in your community. Be sure to include the stoichiometric analysis.
40Chemistry Stoichiometry How
Suggested Instructional Sequence Differentiation Examples
Introduction of mole concept. - What is mole? - Determine the number of rice grains in a given container. Guided practice in calculation of atomic mass, molar mass, and formula mass. Utilize dimensional analysis to convert among mole, gram, volume and number of particles. - Lab Galvanized Iron determine number of atoms of Zn coated on a piece of galvanized iron. - Guided practice mole conversions using mole concept map. Percent of composition - Lab percent of water in popcorn - Lab determining an Empirical formula such as copper sulfate hydrates. Introduction of Stoichiometry - Demonstration electrolysis of water to illustrate the mole ratio. - Lab Use stoichiometric relationship to analyze the amount of silver replaced from silver nitric solution with the copper. Introduction of limiting reagent - Using manipulation to demonstrate limiting reagents (cake recipe) - A research project about the limitation of a natural resource, such as petroleum, copper. Challenge Design a lab to synthesize a quantitative product when given a variety of reactants Design a lab to determine the empirical formula for a given hydrate compound. Adjust Predict the volume of carbon dioxide that would be produced by adding specified amounts of vinegar to various teaspoons of baking soda. Carry out the activity and compare the experimental results with your prediction. Account for any differences in volume. ESOL Create a PowerPoint presentation to explain stoichiometry