Basics of Stoichiometry - Module 1 PDF

Summary

This document provides an overview of the basics of stoichiometry. It explains concepts like the mole, Avogadro's number, and percent composition. The document also presents examples and calculations related to stoichiometric problems.

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M DULE 1
 macroscopic level microscopic level
units = g, L, etc.. units = ???

CHM1311 Basics of Stoichiometry 2
The mole is an amount of substance that contains the
same number of elementary entities as there are carbon-
12 atoms in exactly 12 g of carbon-12.

12C

12.00 g

6.022 141 29 x 1023 carbon atoms

CHM1311 Basics of Stoichiometry 3
 NA = 6.022 141 29 x 1023 mol-1

Amedeo Avogadro
(1776 – 1856)

12 things = 1 dozen things

6.022 x 1023 things = 1 mole of things

CHM1311 Basics of Stoichiometry 4
 molecular sum of atomic masses of
mass
= each atom in the molecule
(in atomic mass units, u)

molar mass, in grams, of one
mass
= mole of the substance
(units = g/mol)

𝒎 𝒎
𝑴𝑴 = 𝒏=
𝒏 𝑴𝑴
CHM1311 Basics of Stoichiometry 5
For H2O:
H
H O
H O H
O H
H H O
O
H H H H
H H
H O O
O
H H
O
H H

Molecular Mass = Molar Mass =
mass of one molecule mass of one mole
18.015 u 18.015 g/mol

CHM1311 Basics of Stoichiometry 6
 Concentration à later

Percent Composition

CHM1311 Basics of Stoichiometry 7
 number of parts of a component in 100 parts of the whole

– ex. 10% means “10 parts x per 100 parts of the whole”

IMPORTANT: must be defined by a unit!

– ex. a rock contains 3.5% gold by mass means 3.5 g of gold
per 100 g of rock

– ex. a bottle of wine contains 10.7% alcohol by volume means
10.7 mL of alcohol per 100 mL of wine

– ex. an isotope occurring in nature with 1.8% abundance
means 1.8 isotopes per 100 atoms overall

CHM1311 Basics of Stoichiometry 8
 number of parts of a component in 100 parts of the whole

𝑎𝑚𝑜𝑢𝑛𝑡 𝑜𝑓 𝑐𝑜𝑚𝑝𝑜𝑛𝑒𝑛𝑡
𝑃𝑒𝑟𝑐𝑒𝑛𝑡 𝐶𝑜𝑚𝑝𝑜𝑠𝑖𝑡𝑖𝑜𝑛 = ×100%
𝑡𝑜𝑡𝑎𝑙 𝑎𝑚𝑜𝑢𝑛𝑡 𝑜𝑓 𝑚𝑖𝑥𝑡𝑢𝑟𝑒

ex. what % of students earned an A grade (A-/A/A+) last year?

𝑃𝑒𝑟𝑐𝑒𝑛𝑡𝑎𝑔𝑒 = ×100%
269 students total

CHM1311 Basics of Stoichiometry 9
 when expressed as a conversion factor, the numerator
and denominator must have the SAME UNITS
– ex. a rock contains 3.5% gold by mass
3.5 g gold 3.5 kg gold 3.5 oz gold
= =
100 g rock 100 kg rock 100 oz rock

– ex. a bottle of wine contains 10.7% alcohol by
volume
10.7 mL EtOH 10.7 L EtOH 10.7 tbsp EtOH
= =
100 mL wine 100 L wine 100 tbsp wine

CHM1311 Basics of Stoichiometry 10
Calculate the mass percent of hydrogen in ammonium
bicarbonate, NH4HCO3.
1. 5.166 %
2. 8.392 %
3. 6.387 %
4. 22.82 %
5. I’m not sure

CHM1311 Basics of Stoichiometry 11
Potassium-40 is one of the few naturally occurring radioactive
isotopes of elements of low atomic number. Its percent
natural abundance among K isotopes is 0.012%. How many 40K
atoms do you ingest by drinking one cup of whole milk
containing 371 mg of K?

0.012 mol 40K
WANT: ? atoms of 40K 100 mol K

0.012 atoms 40K
HAVE: abundance of 40K = 0.012%
100 atoms K
mass of K = 371 mg
39.098 g K
NEED: MM of K = 39.098 g/mol mol K
CHM1311 Basics of Stoichiometry 13
 Potassium-40 is one of the few naturally occurring radioactive
isotopes of elements of low atomic number. Its percent
natural abundance among K isotopes is 0.012%. How many 40K
atoms do you ingest by drinking one cup of whole milk
containing 371 mg of K?

? atoms of 40K
1gK mol K 0.012 mol 40K 6.022x1023 atoms 40K
= 371 mg K x x x x
1000 mg K 39.098 g K 100 mol K mol 40K

= 6.9x1017 atoms of 40K Sept 5 DGD: covers
Dimensional Analysis

CHM1311 Basics of Stoichiometry 14
 Potassium-40 is one of the few naturally occurring radioactive
isotopes of elements of low atomic number. Its percent
natural abundance among K isotopes is 0.012%. How many 40K
atoms do you ingest by drinking one cup of whole milk
containing 371 mg of K?

STEPWISE SOLUTION:
𝟒𝟎
𝒎 𝟒𝟎 𝒂𝒕𝒐𝒎𝒔 𝑲
𝒏= 𝒏( 𝑲) =
𝑴𝑴 𝑵𝑨

atoms of
mass of K mol of K mol of 40K
40K

𝟒𝟎
𝟒𝟎 𝒏( 𝑲)
% 𝑲= ×𝟏𝟎𝟎%
𝒏(𝑲)
CHM1311 Basics of Stoichiometry 15
 chemical equations depict the kind of reactants and
products and their relative amounts in a reaction
the physical state of the reactants and products may
be indicated:
2 H2 (g) + O2 (g) ® 2 H2O (l)

for the dissolution of compound in water, the
following notation may be used:

H2O
NaCl (s) NaCl (aq)

CHM1311 Basics of Stoichiometry 16
 Because of the principle of
the conservation of
matter, an equation must
be balanced.

It must have the same
number of atoms of the
same kind on both sides.
Antoine Lavoisier
1743 – 1794

CHM1311 Basics of Stoichiometry 17
 NO(g) + O2(g) ® NO2(g)

1. Never introduce extraneous atoms to balance.

NO(g) + O2(g) ® NO2(g) + O(g)
X
2. Never change a formula for the purpose of balancing
an equation.

NO(g) + O2(g) ® NO3(g)
X
CHM1311 Basics of Stoichiometry 18
Empirical formula:
simplest whole number RATIO of elements HO

Molecular formula:
H2O2
exact number of atoms of each element

Structural formula: H–O–O–H
shows relative placement and connectivity of atoms

CHM1311 Basics of Stoichiometry 19
 the data obtained from elemental analysis of
a sample:
– elements present
– relative proportions

CHM1311 Basics of Stoichiometry 21
 Elemental
Analysis

Mass
Elements present
Spectrum
and their relative
(or other
proportions
techniques)

EMPIRICAL Molecular MOLECULAR
FORMULA Mass FORMULA

CHM1311 Basics of Stoichiometry 22
 compound + excess O2 (g) ® oxidation products (g)

carbon CO2
hydrogen H2O
nitrogen NO2
sulfur SO2

CHM1311 Basics of Stoichiometry 23
Complete combustion of a 1.505 g sample of an unknown
compound consisting of C, H and S yields 3.149 g CO2, 0.645 g H2O
and some SO2.
a) What is the empirical formula for the unknown?
b) We experimentally determine the molecular mass to be 168.1 u.
Determine the molecular formula of the unknown.

CHM1311 Basics of Stoichiometry 24
 the study of the quantitative aspects of
chemical reactions

if the quantity of a reactant is known, it is
possible to calculate the quantity of product
that will be formed (or vice-versa)

to simplify the process, we use the mole
method: we use units of moles instead of
grams or millilitres

CHM1311 Basics of Stoichiometry 25
Step 1: Identify all reactants and products
Step 2: Balance the chemical equation
Step 3: Follow the mole method

mass of mass of
reactant product
MOLAR MOLAR
MASS MASS
STOICHIOMETRIC
moles of FACTOR moles of
reactant product

CHM1311 Basics of Stoichiometry 26
Lithium, like all alkali metals, reacts readily with water to produce
hydrogen gas and aqueous metal hydroxide:
2 Li (s) + 2 H2O (l) à 2 LiOH (aq) + H2 (g)
How many grams of solid lithium metal is needed to produce 9.89 g
of hydrogen gas?
2 mol Li
WANT: ? g Li 1 mol H2
HAVE: balanced equation
mass of H2 = 9.89 g 6.941 g Li
mol Li
NEED: MM of Li = 6.941 g/mol
MM of H2 = 2.016 g/mol 2.016 g H2
mol H2
CHM1311 Basics of Stoichiometry 27
 Lithium, like all alkali metals, reacts readily with water to produce
hydrogen gas and aqueous metal hydroxide:
2 Li (s) + 2 H2O (l) à 2 LiOH (aq) + H2 (g)
How many grams of solid lithium metal is needed to produce 9.89 g
of hydrogen gas?

mol H2 2 mol Li 6.941 g Li
? g of Li = 9.89 g H2 x x x
2.016 g H2 1 mol H2 mol Li

= 68.1 g Li
MOLAR STOI’C MOLAR
MASS RATIO MASS
mass of moles of moles of mass of
H2 H2 Li Li

CHM1311 Basics of Stoichiometry 28
 stoichiometry and the mole method is
an extremely powerful tool
it can be used with other conversion
factors, such as:
– density
– concentration
– percent composition

CHM1311 Basics of Stoichiometry 29
An alloy used in aircraft structures
consists of 93.7% Al and 6.3% Cu by
mass. The alloy has a density of
2.85 g/cm3. A 0.691 cm3 piece of
the alloy reacts with an excess of
HCl(aq) to produce H2(g) and
AlCl3(aq). If we assume that all the
Al but none of the Cu reacts with
HCl(aq), what is the mass of H2
obtained?

CHM1311 Basics of Stoichiometry 30
 the theoretical yield is the amount of product
expected if the reactants react to completion
the actual yield is always smaller than this value!
– the inverse reaction occurs
– other side-products are products
– difficult to collect all of the product

actual yield
% yield = × 100%
theoretical yield

CHM1311 Basics of Stoichiometry 31
 2 Li (s) + 2 H2O (l) à 2 LiOH (aq) + H2 (g)
For the earlier example, if only 7.82 g of H2 were formed,
what is the yield of the reaction?

7.82 g
9.89 g
= 79.1%

CHM1311 Basics of Stoichiometry 32
Two sets of successive reactions, A à B and B à C, have
respective yields of 48% and 73%.
What is the overall percent yield for conversion of A to C?

1. 66%
2. 48%
3. 73%
4. 35%
5. I’m not sure

CHM1311 Basics of Stoichiometry 33
 the mole and Avogadro’s number
percent composition
empirical vs. molecular formulae
balancing chemical equations
stoichiometry and the mole method
percent yields

CHM1311 Basics of Stoichiometry 35
Complete combustion of 200 g of a CH4/C3H8 mixture that is
25.0% methane and 75.0% propane by mass. What mass (in
g) of carbon dioxide is produced?

Try this on your own – the solution is
posted on Brightspace
CHM1311 Basics of Stoichiometry 36