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5.2: Chemical Equations

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     Learning Objectives
    • Define chemical reaction.
    • Use a balanced chemical equation to represent a chemical reaction.

    Water (H2O) is composed of hydrogen and oxygen. Suppose we imagine a process in which we take some elemental hydrogen (H2) and elemental oxygen (O2) and let them react to make water. The statement

    "hydrogen and oxygen react to make water"

    is one way to represent that process, which is called a chemical reaction. Figure \(\PageIndex{1}\) shows a rather dramatic example of this very reaction.

    imageedit_14_4420384887.jpg
    Figure \(\PageIndex{1}\): The Formation of Water. Hydrogen and oxygen combine to form water. Here, the hydrogen gas in the zeppelin  SS  Hindenburg reacts with oxygen in the air to make water. Source: Photo courtesy of the US Navy. For a video of this see www.youtube.com/watch?v=Cg WHbpMVQ1U.

    To simplify the writing of reactions, we use formulas instead of names when we describe a reaction. We can also use symbols to represent other words in the reaction. A plus sign connects the initial substances (and final substances, if there is more than one), and an arrow (→) represents the chemical change:

    \[\ce{H_2 + O_2 \rightarrow H_2O} \label{Eq1} \]

    This statement is one example of a chemical equation, an abbreviated way of using symbols to represent a chemical change. The substances on the left side of the arrow are called reactants, and the substances on the right side of the arrow are called products. It is not uncommon to include a phase label with each formula—(s) for solid, (ℓ) for liquid, (g) for gas, and (aq) for a substance dissolved in water, also known as an aqueous solution. If we included phase labels for the reactants and products, under normal environmental conditions, the reaction would be as follows:

    \[\ce{H2(g) + O2(g) \rightarrow H2O (ℓ)} \label{Eq2} \]

    Chemical equations can also be used to describe physical changes. We will see examples of this soon.

    This equation is still not complete because it does not satisfy the law of conservation of matter. Count the number of atoms of each element on each side of the arrow. On the reactant side, there are two H atoms and two O atoms; on the product side, there are two H atoms and only one oxygen atom. The equation is not balanced because the number of oxygen atoms on each side is not the same (Figure \(\PageIndex{2}\)).

    imageedit_5_3207276489.jpg
    Figure \(\PageIndex{2}\): Balanced—Yes or No?. By counting the atoms of each element, we can see that the reaction is not balanced as written.

    To make this chemical equation conform to the law of conservation of matter, we must revise the amounts of the reactants and the products as necessary to get the same number of atoms of a given element on each side. Because every substance has a characteristic chemical formula, we cannot change the chemical formulas of the individual substances. For example, we cannot change the formula for elemental oxygen to O. However, we can assume that different numbers of reactant molecules or product molecules may be involved. For instance, perhaps two water molecules are produced, not just one:

    \[\ce{H2(g) + O2 (g) \rightarrow 2H2O (ℓ)} \label{Eq3} \]

    The 2 preceding the formula for water is called a coefficient. It implies that two water molecules are formed. There are now two oxygen atoms on each side of the equation.

    This point is so important that we should repeat it. You cannot change the formula of a chemical substance to balance a chemical reaction! You must use the proper chemical formula of the substance.

    Unfortunately, by inserting the coefficient 2 in front of the formula for water, we have also changed the number of hydrogen atoms on the product side as well. As a result, we no longer have the same number of hydrogen atoms on each side. This can be easily fixed, however, by putting a coefficient of 2 in front of the diatomic hydrogen reactant:

    \[\ce{2H2(g) + O2(g) \rightarrow 2H2O (ℓ)} \label{Eq4} \]

    Now we have four hydrogen atoms and two oxygen atoms on each side of the equation. The law of conservation of matter is satisfied because we now have the same number of atoms of each element in the reactants and in the products. We say that the reaction is balanced (Figure \(\PageIndex{3}\)). The diatomic oxygen has a coefficient of 1, which typically is not written but assumed in balanced chemical equations.

    imageedit_9_5523060824.jpg
    Figure \(\PageIndex{3}\): Balanced—Yes or No?. By counting the atoms of each element, we can see that the reaction is now balanced.

    Proper chemical equations should be balanced. Writing balanced reactions is a chemist’s way of acknowledging the law of conservation of matter.

    Example \(\PageIndex{1}\)

    Is each chemical equation balanced?

    1. 2Na(s) + O2(g) → 2Na2O(s)
    2. CH4(g) + 2O2(g) → CO2(g) + 2H2O(ℓ)
    3. AgNO3(aq) + 2KCl(aq) → AgCl(s) + KNO3(aq)
    Solution
    1. By counting, we find two sodium atoms and two oxygen atoms in the reactants and four sodium atoms and two oxygen atoms in the products. This equation is not balanced.
    2. The reactants have one carbon atom, four hydrogen atoms, and four oxygen atoms. The products have one carbon atom, four hydrogen atoms, and four oxygen atoms. This equation is balanced.
    3. The reactants have one silver atom, one nitrogen atom, three oxygen atoms, two potassium atoms, and two chlorine atoms. The products have one silver atom, one chlorine atom, one potassium atom, one nitrogen atom, and three oxygen atoms. Because there are different numbers of chlorine and potassium atoms, this equation is not balanced.
    Exercise \(\PageIndex{1}\)

    Is each chemical equation balanced?

    1. \(2Hg_{(ℓ)} + O_{2(g)} \rightarrow Hg_2O_{2(s)}\)
    2. \(C_2H_{4(g)} + 2O_{2(g)} \rightarrow 2CO_{2(g)} + 2H_2O_{(ℓ)}\)
    3. \(Mg(NO_3)_{2(s)} + 2Li_{(s)} \rightarrow Mg_{(s)} + 2LiNO_{3(s)}\).
    Answer a:

    balanced

    Answer b:

    O is not balanced; the 4 atoms of oxygen on the left does not balance with the 6 oxygen atoms on the right

    Answer c:

    balanced

    How does one balance a chemical equation, starting with the correct formulas of the reactants and products? Basically, a back-and-forth approach is adopted, counting the number of atoms of one element on one side, checking the number of atoms of that element on the other side, and changing a coefficient if necessary. Then check another element, going back and forth from one side of the equation to another, until each element has the same number of atoms on both sides of the arrow. In many cases, it does not matter which element is balanced first and which is balanced last, as long as all elements have the same number of atoms on each side of the equation.

    Below are guidelines for writing and balancing chemical equations.

    1. Determine the correct chemical formulas for each reactant and product. Write the skeleton equation.
    2. Count the number of atoms of each element that appears as a reactant and as a product. If a polyatomic ion is unchanged on both sides of the equation, count it as a unit.
    3. Balance each element one at a time by placing coefficients in front of the formulas. No coefficient is written for a 1. It is best to begin by balancing elements that only appear in one chemical formula on each side of the equation. NEVER change the subscripts in a chemical formula - you can only balance equations by using coefficients.
    4. Check each atom or polyatomic ion to be sure that they are equal on both sides of the equation.
    5. Make sure that all coefficients are in the lowest possible ratio. If necessary, reduce to the lowest ratio.

    For example, to balance the equation

    Step 1: Write the skeleton equation with the correct formulas.

    \[\ce{CH4 + Cl2 \rightarrow CCl4 + HCl} \label{Eq5} \]

    Step 2: Count the number of each atom or polyatomic ion on both sides of the equation.

    \[\begin{array}{ll} \textbf{Reactants} & \textbf{Products} \\ 1 \: \ce{C} \: \text{atom} & 1 \: \ce{C} \: \text{atom} \\ 4 \: \ce{H} \: \text{ions} & 1 \: \ce{H} \: \text{ions} \\ 2 \: \ce{Cl} \: \text{atom} & 5 \: \ce{Cl} \: \text{atoms} \end{array} \nonumber \]

    Step 3: We find that both sides are already balanced with one carbon atom. So we proceed to balance the hydrogen atoms. We find that the reactant side has four hydrogen atoms, so the product side must also have four hydrogen atoms. This is balanced by putting a 4 in front of the HCl:

    \[\ce{CH4 + Cl2 \rightarrow CCl4 + 4HCl } \label{Eq6} \]

    \[\begin{array}{ll} \textbf{Reactants} & \textbf{Products} \\ 1 \: \ce{C} \: \text{atom} & 1 \: \ce{C} \: \text{atom} \\ 4 \: \ce{H} \: \text{ions} & 4 \: \ce{H} \: \text{ions} \\ 2 \: \ce{Cl} \: \text{atom} & 8 \: \ce{Cl} \: \text{atoms} \end{array} \nonumber \]

    Now each side has four hydrogen atoms. The product side has a total of eight chlorine atoms (four from the \(CCl_4\) and four from the four molecules of HCl), so we need eight chlorine atoms as reactants. Because elemental chlorine is a diatomic molecule, we need four chlorine molecules to get a total of eight chlorine atoms. We add another 4 in front of the Cl2 reactant:

    \[\ce{CH4 + 4Cl2 \rightarrow CCl4 + 4HCl } \label{Eq7} \]

    \[\begin{array}{ll} \textbf{Reactants} & \textbf{Products} \\ 1 \: \ce{C} \: \text{atom} & 1 \: \ce{C} \: \text{atom} \\ 4 \: \ce{H} \: \text{ions} & 4 \: \ce{H} \: \text{ions} \\ 8 \: \ce{Cl} \: \text{atom} & 8 \: \ce{Cl} \: \text{atoms} \end{array} \nonumber \]

    Step 3: Now we check: each side has one carbon atom, four hydrogen atoms, and eight chlorine atoms. The chemical equation is balanced. And, the coefficients are in the lowest possible ratio.

    Example \(\PageIndex{2}\)

    Aqueous solutions of lead (II) nitrate and sodium chloride are mixed. The products of the reaction are an aqueous solution of sodium nitrate and a solid precipitate of lead (II) chloride. Write the balanced chemical equation for this reaction.

    Solution

    Step 1: Write the skeleton equation with the correct formulas.

    \[\ce{Pb(NO_3)_2} \left( aq \right) + \ce{NaCl} \left( aq \right) \rightarrow \ce{NaNO_3} \left( aq \right) + \ce{PbCl_2} \left( s \right) \nonumber \]

    Step 2: Count the number of each atom or polyatomic ion on both sides of the equation.

    \[\begin{array}{ll} \textbf{Reactants} & \textbf{Products} \\ 1 \: \ce{Pb} \: \text{atom} & 1 \: \ce{Pb} \: \text{atom} \\ 2 \: \ce{NO_3^-} \: \text{ions} & 1 \: \ce{NO_3^-} \: \text{ions} \\ 1 \: \ce{Na} \: \text{atom} & 1 \: \ce{Na} \: \text{atom} \\ 1 \: \ce{Cl} \: \text{atom} & 2 \: \ce{Cl} \: \text{atoms} \end{array} \nonumber \]

    Step 3: Solve. The nitrate ions and the chlorine atoms are unbalanced. Start by placing a 2 in front of the \(\ce{NaCl}\). This increases the reactant counts to 2 \(\ce{Na}\) atoms and 2 \(\ce{Cl}\) atoms. Then place a 2 in front of the \(\ce{NaNO_3}\). The result is:

    \[\ce{Pb(NO_3)_2} \left( aq \right) + 2 \ce{NaCl} \left( aq \right) \rightarrow 2 \ce{NaNO_3} \left( aq \right) + \ce{PbCl_2} \left( s \right) \nonumber \]

    Step 4: The new count for each atom and polyatomic ion becomes:

    \[\begin{array}{ll} \textbf{Reactants} & \textbf{Products} \\ 1 \: \ce{Pb} \: \text{atom} & 1 \: \ce{Pb} \: \text{atom} \\ 2 \: \ce{NO_3^-} \: \text{ions} & 2 \: \ce{NO_3^-} \: \text{ions} \\ 2 \: \ce{Na} \: \text{atom} & 2 \: \ce{Na} \: \text{atom} \\ 2 \: \ce{Cl} \: \text{atom} & 2 \: \ce{Cl} \: \text{atoms} \end{array} \nonumber \]

    Step 5: Think about the result.

    The equation is now balanced since there are equal numbers of atoms of each element on both sides of the equation. And, the coefficients are in the lowest possible ratio.

    Exercise \(\PageIndex{2}\)

    Fermentation is a biochemical process that enables yeast cells to live in the absence of oxygen. Hum ans have exploited it for centuries to produce wine and beer and make bread rise. In fermentation, sugars such as glucose (C6H12O6) are converted to ethanol (C2H5OH) and carbon dioxide CO2. Write a balanced chemical reaction for the fermentation of glucose.

    imageedit_23_2460123050.jpg
    Commercial use of fermentation. (a) Microbrewery vats are used to prepare beer. (b) The fermentation of glucose by yeast cells is the reaction that makes beer production possible.
    Answer

    \[\ce{C6H12O6(s) → 2C2H5OH(l) + 2CO2(g)} \nonumber \]

     

    Key Takeaway

    Chemical reactions are represented by chemical equations that list reactants and products. Proper chemical equations are balanced; the same number of each element’s atoms appears on each side of the equation.


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