4.9 Oxidation-Reduction Reactions

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4.9 Oxidation-Reduction Reactions We have seen that many important substances are ionic. Sodium chloride, can be formed by the reaction of elemental sodium and chlorine: 2Na(s) Cl 2 (g) 2NaCl(s) This process is represented in Fig. 4.19. Reaction like this one, in which one or more electrons are transferred, are called oxidation-reduction reactions or redox reactions. P.154

Many important chemical reactions involve oxidation and reduction. Combustion reactions, which provide most of the energy to power our civilization, also involve oxidation and reduction. An example is the reaction of methane with oxygen: CH 4 (g) 2O 2 (g) CO 2 (g) 2H 2 O(g) energy P.154

Even though none of the reactants or products in this reaction is ionic, the reaction is still assumed to involve a transfer of electrons from carbon to oxygen. P.154

Figure 4.19 The reaction of solid sodium and gaseous chlorine to form solid sodium chloride. P.155

Oxidation States The oxidation states of atoms in covalent compounds are obtained by arbitrarily assigning the electrons (which are actually shared) to particular atoms. We do this as follows: For a covalent bond between two identical atoms, the electrons are split equally between the two. In cases where two different atoms are involved (and the electrons are thus shared unequally), the shared electrons are assigned completely to the atom that has the stronger attraction for electrons. P.155

A series of rules for assigning oxidation states that are summarized in Table 4.2. To apply these rules recognize that the sum of the oxidation states must be zero for an electrically neutral compound. P.156

TABLE 4.2 Rules for Assigning Oxidation States P.156

Oxidation of copper metal by nitric acid. The copper atoms lose two electrons to form Cu 2 ions, which give a deep green color that becomes turquoise when diluted with water. P.156

Sample Exercise 4.16 Assigning Oxidation States Assign oxidation states to all atoms in the following. a. CO 2 b. SF 6 c. NO 3 Solution a. The oxidation state of oxygen is 2. P.157

Sample Exercise 4.16 The sum is zero as required: b. Reality Check: 6 6( 1) 0 P.158

Sample Exercise 4.16 c. Reality Check: 5 3( 2) 1 See Exercises 4.67 through 4.70 P.158

For Fe 3 O 4, the rules assume that all the iron atoms are equal, when in fact this compound can best be viewed ascontaining four O 2 ions, two Fe 3 ions, and one Fe 2 ion per formula unit. Magnetite is a magnetic ore containing Fe 3 O 4. Note that the compass needle points toward the ore. P.158

The Characteristics of Oxidation- Reduction Reactions Oxidation state CH 4 (g) 2O 2 (g) CO 2 (g) 2H 2 O(g) 4 1 0 4 2 1 2 (each H) (each O) (each H) Note that the oxidation state for oxygen in O 2 is 0 because it is in elemental form. Note that carbon undergoes a change in oxidation state from 4 in CH 4 to 4 in CO 2. CH CO 4 2 8e 4 4 P.158

Each oxygen changes from an oxidation state of 0 in O 2 to 2 in H 2 O and CO 2, signifying a gain of two electrons per atom. 2O 2 8e CO 2 2H 2 O 0 4( 2) 8 Oxidation is an increase in oxidation state (a loss of electrons). P.159

Reduction is a decrease in oxidation state (a gain of electrons). Thus in the reaction. 2Na(s) Cl 2 (g) 2NaCl(s) 0 0 1 1 Cl 2 is called the oxidizing agent (electron acceptor), and Na is called the reducing agent (electron donor). These terms are summarized in Fig. 4.20. P.159

Concerning the reaction CH 4 (g) 2O 2 (g) CO 2 (g) 2H 2 O(g) 4 1 0 4 2 1 2 Carbon is oxidized because there has been an increase in its oxidation state (carbon has formally lost electrons). Oxygen is reduced because there has been a decrease in its oxidation state (oxygen has formally gained electrons). CH 4 is the reducing agent. O 2 is the oxidizing agent. P.159

Figure 4.20 A summary of an oxidationreduction process, in which M is oxidized and X is reduced. P.159

4.10 Balancing Oxidation-Reduction Equations The Half-Reaction Method for Balancing Oxidation-Reduction Reactions in Aqueous Solutions For oxidation-reduction reactions that occur in aqueous solution, it is useful to separate the reaction into two halfreactions: involving oxidation and the other involving reduction. Ce 4 (aq) Sn 2 (aq) Ce 3 (aq) Sn 4 (aq) P.162

The substance being reduced, Ce 4 (aq) Ce 3 (aq) The substance being oxidized, Sn 2 (aq) Sn 4 (aq) The general procedure is to balance the equations for the half-reactions separately and then to add them to obtain the overall balanced equation. P.162

The Half-Reaction Method for Balancing Equations for Oxidation-Reduction Reactions Occurring in Acidic Solution 1 Write separate equations for the oxidation and reduction half-reactions. 2 For each half-reaction, a. Balance all the element except hydrogen and oxygen. b. Balance oxygen using H 2 O. c. Balance hydrogen using H. d. Balance the charge using electrons. 3 If necessary, multiply one or both balanced halfreactions by an integer to equalize the number of electrons transferred in the two halfreactions. P.162

4 Add the half-reactions, and cancel identical species. 5 Check that the elements and charges are balanced. P.163

These steps are summarized by the following flowchart: P.163

We will illustrate this method by balancing the equation for the reaction between permanganate and iron(ii) ions in acidic solution: Acid MnO 4 (aq) Fe 2 (aq) Fe 3 (aq) Mn 2 (aq) 1 Identify and write equations for the half-reactions. MnO 4 Mn 2 7 2 (each O) 2 P.163

This is the reduction half-reaction. Fe 2 Fe 3 2 3 2 Balance each half-reaction. MnO 4 (aq) Mn 2 (aq) a. The manganese is balanced. b. We balance oxygen by adding 4H 2 O to the right side of the equation: P.163

MnO 4 (aq) Mn 2 (aq) 4H 2 O(l) c. Balance hydrogen by adding 8H to the left side: 8H (aq) MnO 4 (aq) Mn 2 (aq) 4H 2 O(l) d. Balance the charge using electrons. 8H (aq) MnO 4 (aq) Mn 2 (aq) 4H 2 O(l) 8 1 2 0 7 2 P.164

We can equalize the charges by adding five electrons to the left side: 5e 8H (aq) MnO 4 (aq) Mn 2 (aq) 4H 2 O(l) 2 2 Both the elements and the charges are now balanced. For the oxidation reaction Fe 2 (aq) Fe 3 (aq) P.164

Fe 2 (aq) 2 Fe 2 (aq) Fe 3 (aq) 3 Fe 3 (aq) e 2 2 3 Equalize the electron transfer in the two halfreactions. 5Fe 2 (aq) 5Fe 3 (aq) 5e P.164

4 Add the half-reactions. 5e 5Fe 2 (aq) MnO 4 (aq) 8H (aq) 5Fe 3 (aq) Mn 2 (aq) 4H 2 O(l) 5e Note that the electrons cancel (as they must) to give the final balanced equation: 5Fe 2 (aq) MnO 4 (aq) 8H (aq) 5Fe 3 (aq) Mn 2 (aq) 4H 2 O(l) P.164

5 Check that elements and charges are balanced. Elements balance: 5Fe, 1 Mn, 4O, 8H 5Fe, 1 Mn, 4O, 8H Charges balance: 5(2 ) (1 ) 8(1 ) 17 5(3 ) (2 ) 0 17 The equation is balanced. P.165

The Half-Reaction Method for Balancing Equations for Oxidation-Reduction Reactions Occurring in Basic Solution 1 Use the half-reaction method as specified for acidic solutions to obtain the final balanced equation as if H ions were present. 2 To both sides of the equation obtained above, add a number of OH ions that is equal to the number of H ions. (We want to eliminate H by forming H 2 O.) 3 Form H 2 O on the side containing both H and OH ions, and eliminate the number of H 2 O molecules that appear on both sides of the equation. 4 Check that elements and charges are balanced. P.166

This method is summarized by the following flowchart: P.167

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