5: Chemical Reactions

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Introduction to Module

Chemical reactions describe how substances change into new substances. Chemists represent these changes using chemical equations, which show the reactants (starting materials) and products (substances formed). Writing a correct chemical equation requires identifying the chemical formulas of the reactants and products and arranging them to represent the reaction that occurs.

Because matter is conserved in chemical reactions, chemical equations must follow the law of conservation of mass, which states that atoms are neither created nor destroyed during a reaction. To satisfy this law, equations must be balanced, meaning the number of atoms of each element is the same on both sides of the equation. Balancing chemical equations involves adjusting coefficients (numbers placed before formulas) so that the atoms of each element are conserved.

Once an equation is balanced, it can be used to perform stoichiometric calculations, which allow chemists to determine the quantitative relationships between reactants and products. The coefficients in a balanced equation represent the mole ratios that connect the amounts of substances involved in the reaction. These mole ratios make it possible to calculate how much product will form from a given amount of reactant or how much reactant is needed to produce a certain quantity of product.

In many reactions, the reactants are not present in the exact proportions required by the balanced equation. The limiting reactant is the reactant that is completely consumed first and therefore limits the amount of product that can be formed. Once the limiting reactant is used up, the reaction stops, even if other reactants remain in excess.

In practice, the amount of product obtained in an experiment is often less than the theoretical amount predicted by stoichiometric calculations. The percent yield compares the actual yield obtained in a reaction to the theoretical yield calculated from the balanced equation. It is expressed as a percentage and provides insight into the efficiency of a chemical reaction.

Together, writing and balancing chemical equations, performing stoichiometric calculations, identifying limiting reactants, and determining percent yield are essential skills in chemistry. These concepts allow chemists to predict reaction outcomes, measure reaction efficiency, and apply quantitative reasoning to chemical processes.

Learning Outcomes

By the end of this module, students are expected to:

Define chemical reaction, chemical equation, reactant, and product.
Write a chemical equation from a word reaction using chemical formulas for reactants and products.
Balance chemical equations by changing stoichiometric coefficients.
Determine amounts of reactant required or product formed using stoichiometry.
Identify the limiting reactant in a reaction.
Define theoretical yield, actual yield, and percent yield.
Calculate the percent yield of a reaction.

5.1: Stoichiometry of Formulas and Equations
This page covers the principles of chemical equations, emphasizing the Law of Conservation of Mass and the need for balancing through coefficients. It includes guidelines for adjusting equations, identifying limiting reactants, and calculating theoretical and percent yields. The balancing process is enhanced with techniques for addressing complex substances and polyatomic ions, while practical examples demonstrate the concepts.
5.2: Student Activity
This page offers exercises on chemical reactions, emphasizing the conversion of reactants into balanced equations and stoichiometric calculations. It addresses balancing equations involving different compounds, identifying limiting reactants, and calculating product masses for specific reactions, such as those with diborane and aluminum sulfide.
5.3: Assessment

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