1.4.5 Reaction Stoichiometry

Juliana Antonipillai; Durga Dharmadana; Narin Osman; Nhiem Tran; Terry Piva; Celine Valery

1.4.5 Reaction Stoichiometry

Learning Objectives

By the end of this section, you will be able to:

Explain the concept of stoichiometry as it pertains to chemical reactions
Use balanced chemical equations to derive stoichiometric factors relating amounts of reactants and products
Perform stoichiometric calculations involving mass, moles, and solution molarity

A balanced chemical equation provides a great deal of information in a very succinct format. Chemical formulas provide the identities of the reactants and products involved in the chemical change, allowing classification of the reaction. Coefficients provide the relative numbers of these chemical species, allowing a quantitative assessment of the relationships between the amounts of substances consumed and produced by the reaction. These quantitative relationships are known as the reaction’s stoichiometry, a term derived from the Greek words stoicheion (meaning “element”) and metron (meaning “measure”). In this module, the use of balanced chemical equations for various stoichiometric applications is explored.

The general approach to using stoichiometric relationships is similar in concept to the way people go about many common activities. Food preparation, for example, offers an appropriate comparison. A recipe for making eight pancakes calls for 1 cup pancake mix, 3/4 cup milk, and one egg. The “equation” representing the preparation of pancakes per this recipe is

1 cup mix + \frac{3}{4} cup milk + 1 egg ⟶ 8 pancakes

24 pancakes \times \frac{1 egg}{8 pancakes} = 3 eggs

N_{2} (g) + 3 H_{2} (g) ⟶ 2 {NH}_{3} (g)

\frac{2 {NH}_{3} molecules}{3 H_{2} molecules} or \frac{2 doz {NH}_{3} molecules}{3 doz H_{2} molecules} or \frac{2 mol {NH}_{3} molecules}{3 mol H_{2} molecules}

EXAMPLE 1.4.5.2

Number of Product Molecules Generated by a Reaction

How many carbon dioxide molecules are produced when 0.75 mol of propane is combusted according to this equation?

C_{3} H_{8} + 5 O_{2} ⟶ 3 {CO}_{2} + 4 H_{2} O

The approach here is the same as for Example 1.4.5.2, though the absolute number of molecules is requested, not the number of moles of molecules. This will simply require use of the moles-to-numbers conversion factor, Avogadro’s number.

The balanced equation shows that carbon dioxide is produced from propane in a 3:1 ratio:

\frac{3 mol {CO}_{2}}{1 mol C_{3} H_{8}}

Using this stoichiometric factor, the provided molar amount of propane, and Avogadro’s number,

This figure shows two pink rectangles. The first is labeled, “Moles of C subscript 3 H subscript 8.” This rectangle is followed by an arrow pointing right to a second rectangle labeled, “Moles of C O subscript 2.”

0.75 mol C_{3} H_{8} \times \frac{3 mol {CO}_{2}}{1 mol C_{3} H_{8}} \times \frac{6.022 \times 10^{23} {CO}_{2} molecules}{mol {CO}_{2}} = 1.4 \times 10^{24} {CO}_{2} molecules

Check Your Learning

How many NH₃ molecules are produced by the reaction of 4.0 mol of Ca(OH)₂ according to the following equation:

{({NH}_{4})}_{2} {SO}_{4} + Ca {(OH)}_{2} ⟶ 2 {NH}_{3} + {CaSO}_{4} + 2 H_{2} O

ANSWER:

4.8 $\times$ 10²⁴ NH₃ molecules

These examples illustrate the ease with which the amounts of substances involved in a chemical reaction of known stoichiometry may be related. Directly measuring numbers of atoms and molecules is, however, not an easy task, and the practical application of stoichiometry requires that we use the more readily measured property of mass.

EXAMPLE 1.4.5.3

Relating Masses of Reactants and Products

What mass of sodium hydroxide, NaOH, would be required to produce 16 g of the antacid milk of magnesia [magnesium hydroxide, Mg(OH)₂] by the following reaction?

{MgCl}_{2} (a q) + 2 NaOH (a q) ⟶ Mg {(OH)}_{2} (s) + 2 NaCl (a q)

The approach used previously in Example 1.4.5.1 and 1.4.5.2 is likewise used here; that is, we must derive an appropriate stoichiometric factor from the balanced chemical equation and use it to relate the amounts of the two substances of interest. In this case, however, masses (not molar amounts) are provided and requested, so additional steps of the sort learned in the previous chapter are required. The calculations required are outlined in this flowchart:

16 g Mg {(OH)}_{2} \times \frac{1 mol Mg {(OH)}_{2}}{58.3 g Mg {(OH)}_{2}} \times \frac{2 mol NaOH}{1 mol Mg {(OH)}_{2}} \times \frac{40.0 g NaOH}{mol NaOH} = 22 g NaOH

What mass of gallium oxide, Ga₂O₃, can be prepared from 29.0 g of gallium metal? The equation for the reaction is

$4 Ga + 3 O_{2} ⟶ 2 {Ga}_{2} O_{3} .$

ANSWER:

39.0 g

EXAMPLE 1.4.5.4

Relating Masses of Reactants

What mass of oxygen gas, O₂, from the air is consumed in the combustion of 702 g of octane, C₈H₁₈, one of the principal components of gasoline?

2 C_{8} H_{18} + 25 O_{2} ⟶ 16 {CO}_{2} + 18 H_{2} O

The approach required here is the same as for the Example 1.4.5.3, differing only in that the provided and requested masses are both for reactant species.

702 g C_{8} H_{18} \times \frac{1 mol C_{8} H_{18}}{114.23 g C_{8} H_{18}} \times \frac{25 mol O_{2}}{2 mol C_{8} H_{18}} \times \frac{32.00 g O_{2}}{mol O_{2}} = 2.46 \times 10^{3} g O_{2}

What mass of CO is required to react with 25.13 g of Fe₂O₃ according to the equation

${Fe}_{2} O_{3} + 3 CO ⟶ 2 Fe + 3 {CO}_{2} ?$

ANSWER:

13.22 g

These examples illustrate just a few instances of reaction stoichiometry calculations. Numerous variations on the beginning and ending computational steps are possible depending upon what particular quantities are provided and sought (volumes, solution concentrations, and so forth). Regardless of the details, all these calculations share a common essential component: the use of stoichiometric factors derived from balanced chemical equations. Figure 1.4.5.2 provides a general outline of the various computational steps associated with many reaction stoichiometry calculations.

This flowchart shows 10 rectangles connected by double headed arrows. To the upper left, a rectangle is shaded lavender and is labeled, “Volume of pure substance A.” This rectangle is followed by a horizontal double headed arrow labeled, “Density.” It connects to a second rectangle which is shaded yellow and is labeled, “Mass of A.” This rectangle is followed by a double headed arrow which is labeled, “Molar Mass,” that connects to a third rectangle which is shaded pink and is labeled, “Moles of A.” To the left of this rectangle is a horizontal double headed arrow labeled, “Molarity,” which connects to a lavender rectangle which is labeled, “Volume of solution A.” The pink, “Moles of A,” rectangle is also connected with a double headed arrow below and to the left. This arrow is labeled “Avogadro’s number.” It connects to a green shaded rectangle that is labeled, “Number of particles of A.” To the right of the pink “Moles of A,” rectangle is a horizontal double headed arrow which is labeled, “Stoichiometric factor.” It connects to a second pink rectangle which is labeled, “Moles of B.” A double headed arrow which is labeled, “Molar mass,” extends from the top of this rectangle above and to the right to a yellow shaded rectangle labeled, “Mass of B.” A horizontal double headed arrow which is labeled, “Density” links to a lavender rectangle labeled, “Volume of substance B,” to the right. A horizontal double headed arrow labeled, “Molarity,” extends right to the of the pink “Moles of B” rectangle. This arrow connects to a lavender rectangle that is labeled, “Volume of substance B.” Another double headed arrow extends below and to the right of the pink “Moles of B” rectangle. This arrow is labeled “Avogadro’s number,” and it extends to a green rectangle which is labeled, “Number of particles of B.” — Figure 1.4.5.2 The flowchart depicts the various computational steps involved in most reaction stoichiometry calculations.

Chemistry in Everyday Life

Airbags

Airbags (Figure 1.4.5.3) are a safety feature provided in most automobiles since the 1990s. The effective operation of an airbag requires that it be rapidly inflated with an appropriate amount (volume) of gas when the vehicle is involved in a collision. This requirement is satisfied in many automotive airbag systems through use of explosive chemical reactions, one common choice being the decomposition of sodium azide, NaN₃. When sensors in the vehicle detect a collision, an electrical current is passed through a carefully measured amount of NaN₃ to initiate its decomposition:

2 {NaN}_{3} (s) ⟶ 3 N_{2} (g) + 2 Na (s)

This photograph shows the inside of an automobile from the driver’s side area. The image shows inflated airbags positioned just in front of the driver’s and passenger’s seats and along the length of the passenger side over the windows. A large, round airbag covers the steering wheel. — Figure 1.4.5.3 Airbags deploy upon impact to minimize serious injuries to passengers. (credit: Jon Seidman)

Section Summary

The coefficients in a balanced chemical equation provide the quantitative relationships (reaction’s stoichiometry) between reactants and products.
Knowing the reaction’s stoichiometry is important to determine the amount of reactants and products resulted from the reaction.

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1.4.5 Reaction Stoichiometry

Learning Objectives

EXAMPLE 1.4.5.1

Moles of Reactant Required in a Reaction

Check Your Learning

EXAMPLE 1.4.5.2

Number of Product Molecules Generated by a Reaction

Check Your Learning

ANSWER:

EXAMPLE 1.4.5.3

Relating Masses of Reactants and Products

EXAMPLE 1.4.5.4

Relating Masses of Reactants

Chemistry in Everyday Life

Airbags

Section Summary

License

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