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15.3: Lewis Acids and Bases

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    452842
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    Learning Objectives

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

    • Explain the Lewis model of acid-base chemistry
    • Write equations for the formation of adducts and complex ions

    In 1923, G. N. Lewis proposed a generalized definition of acid-base behavior in which acids and bases are identified by their ability to accept or to donate a pair of electrons and form a coordinate covalent bond.

    A coordinate covalent bond (or dative bond) occurs when one of the atoms in the bond provides both bonding electrons. For example, a coordinate covalent bond occurs when a water molecule combines with a hydrogen ion to form a hydronium ion. A coordinate covalent bond also results when an ammonia molecule combines with a hydrogen ion to form an ammonium ion. Both of these equations are shown here.

    This figure shows two reactions represented with Lewis structures. The first shows an O atom bonded to two H atoms. The O atom has two lone pairs of electrons. There is a plus sign and then an H atom with a superscript positive sign followed by a right-facing arrow. The next Lewis structure is in brackets and shows an O atom bonded to three H atoms. There is one lone pair of electrons on the O atom. Outside of the brackets is a superscript positive sign. The second reaction shows an N atom bonded to three H atoms. The N atom has one lone pair of electrons. There is a plus sign and then an H superscript positive sign. After the H superscript positive sign is a right-facing arrow. The next Lewis structure is in brackets. It shows an N atom bonded to four H atoms. There is a superscript positive sign outside the brackets.

    Reactions involving the formation of coordinate covalent bonds are classified as Lewis acid-base chemistry. The species donating the electron pair that compose the bond is a Lewis base, the species accepting the electron pair is a Lewis acid, and the product of the reaction is a Lewis acid-base adduct. As the two examples above illustrate, Brønsted-Lowry acid-base reactions represent a subcategory of Lewis acid reactions, specifically, those in which the acid species is H+. A few examples involving other Lewis acids and bases are described below.

    The boron atom in boron trifluoride, BF3, has only six electrons in its valence shell. Being short of the preferred octet, BF3 is a very good Lewis acid and reacts with many Lewis bases; a fluoride ion is the Lewis base in this reaction, donating one of its lone pairs:

    This figure illustrates a chemical reaction using structural formulas. On the left, an F atom is surrounded by four electron dot pairs and has a superscript negative symbol. This structure is labeled below as “Lewis base.” Following a plus sign is another structure which has a B atom at the center and three F atoms single bonded above, right, and below. Each F atom has three pairs of electron dots. This structure is labeled below as “Lewis acid.” Following a right pointing arrow is a structure in brackets that has a central B atom to which 4 F atoms are connected with single bonds above, below, to the left, and to the right. Each F atom in this structure has three pairs of electron dots. Outside the brackets is a superscript negative symbol. This structure is labeled below as “Acid-base adduct.”

    In the following reaction, each of two ammonia molecules, Lewis bases, donates a pair of electrons to a silver ion, the Lewis acid:

    This figure illustrates a chemical reaction using structural formulas. On the left side, a 2 preceeds an N atom which has H atoms single bonded above, to the left, and below. A single electron dot pair is on the right side of the N atom. This structure is labeled below as “Lewis base.” Following a plus sign is an A g atom which has a superscript plus symbol. Following a right pointing arrow is a structure in brackets that has a central A g atom to which N atoms are connected with single bonds to the left and to the right. Each of these N atoms has H atoms bonded above, below, and to the outside of the structure. Outside the brackets is a superscript plus symbol. This structure is labeled below as “Acid-base adduct.”

    Nonmetal oxides act as Lewis acids and react with oxide ions, Lewis bases, to form oxyanions:

    This figure illustrates a chemical reaction using structural formulas. On the left, an O atom is surrounded by four electron dot pairs and has a superscript 2 negative. This structure is labeled below as “Lewis base.” Following a plus sign is another structure which has an S atom at the center. O atoms are single bonded above and below. These O atoms have three electron dot pairs each. To the right of the S atom is a double bonded O atom which has two pairs of electron dots. This structure is labeled below as “Lewis acid.” Following a right pointing arrow is a structure in brackets that has a central S atom to which 4 O atoms are connected with single bonds above, below, to the left, and to the right. Each of the O atoms has three pairs of electron dots. Outside the brackets is a superscript 2 negative. This structure is labeled below as “Acid-base adduct.”

    Many Lewis acid-base reactions are displacement reactions in which one Lewis base displaces another Lewis base from an acid-base adduct, or in which one Lewis acid displaces another Lewis acid:

    Two chemical reactions in two rows using structural formulas. First row, to the left, in brackets is a structure with a central A g atom to which N atoms are connected with single bonds to the left and right. Each N atom has H atoms bonded above, below, and to the outside. Outside the brackets is a superscript plus symbol. This structure is labeled “Acid-base adduct.” Following a plus sign is a 2 and another structure in brackets that shows a C atom triple bonded to an N atom. The C atom has an unshared electron pair on its left side and the N atom has an unshared pair on its right side. Outside the brackets to the right is a superscript negative symbol. This structure is labeled “Base.” Following a right pointing arrow is a structure in brackets with a central A g atom to which 4 FC atoms are connected with single bonds to the left and right. At each of the two ends, N atoms are triple bonded to the C atoms. The N atoms each have an unshared electron pair at the end of the structure. Outside the brackets is a superscript negative symbol. This structure is labeled “New adduct.” Following a plus sign is an N atom with H atoms single bonded above, to the left, and below. A single electron dot pair is on the left side of the N atom. This structure is labeled “New base.” In the second row, on the left side in brackets is a structure with a central C atom. O atoms, each with three unshared electron pairs, are single bonded above and below and a third O atom, with two unshared electron pairs, is double bonded to the right. Outside the brackets is a superscript 2 negative. This structure is labeled “Acid-base adduct.” Following a plus sign is another structure with an S atom at the center. O atoms are single bonded above and below. These O atoms have three electron dot pairs each. To the right of the S atom is a double bonded O atom which has two pairs of electron dots. This structure is labeled “Acid.” Following a right pointing arrow is a structure in brackets with a central S atom to which 4 O atoms are connected with single bonds above, below, left, and right. Each of the O atoms has three pairs of electron dots. Outside the brackets is a superscript 2 negative. This structure is labeled “New adduct.” Following a plus sign is a structure with a central C atom that has two O atoms, each with two unshared electron pairs, double bonded to the left and right.

    Another type of Lewis acid-base chemistry involves the formation of a complex ion (or a coordination complex) comprising a central atom, typically a transition metal cation, surrounded by ions or molecules called ligands. These ligands can be neutral molecules like H2O or NH3, or ions such as CN or OH. Often, the ligands act as Lewis bases, donating a pair of electrons to the central atom. These types of Lewis acid-base reactions are examples of a broad subdiscipline called coordination chemistry—the topic of another chapter in this text.

    The equilibrium constant for the reaction of a metal ion with one or more ligands to form a coordination complex is called a formation constant (Kf) (sometimes called a stability constant). For example, the complex ion

    A Cu atom is bonded to two C atoms. Each of these C atoms is triple bonded to an N atom. Each N atom has two dots on the side of it.

    is produced by the reaction

    \[\ce{Cu^{+}(aq) + 2 CN^{-}(aq) <=> Cu(CN)2^{-}(aq)} \nonumber \]

    The formation constant for this reaction is

    \[K_{ f }=\frac{\left[ \ce{Cu(CN)2^{-}} \right]}{\left[ \ce{Cu^{+}} \right]\left[ \ce{CN^{-}}\right]^2} \nonumber \]

    Alternatively, the reverse reaction (decomposition of the complex ion) can be considered, in which case the equilibrium constant is a dissociation constant (Kd). Per the relation between equilibrium constants for reciprocal reactions described, the dissociation constant is the mathematical inverse of the formation constant, Kd = Kf–1. A tabulation of formation constants is provided in Appendix K.

    As an example of dissolution by complex ion formation, let us consider what happens when we add aqueous ammonia to a mixture of silver chloride and water. Silver chloride dissolves slightly in water, giving a small concentration of Ag+ (\([\ce{Ag^{+}}] = 1.3 \times 10^{–5} ~\text{M}\)):

    \[\ce{AgCl(s) <=> Ag^{+}(aq) + Cl^{-}(aq)} \nonumber \]

    However, if NH3 is present in the water, the complex ion, \(\ce{Ag(NH3)2^{+}}\) can form according to the equation:

    \[\ce{Ag^{+}(aq) + 2 NH3(aq) <=> Ag(NH3)2^{+}(aq)} \nonumber \]

    with

    \[K_{ f }=\dfrac{[ \ce{Ag(NH3)2^{+}} ]}{[ \ce{Ag^{+}} ][\ce{NH3}]^2}=1.7 \times 10^7 \nonumber \]

    The large size of this formation constant indicates that most of the free silver ions produced by the dissolution of AgCl combine with NH 3 to form \(\ce{Ag(NH3)2^{+}}\). As a consequence, the concentration of silver ions, \(\ce{[Ag^{+}]}\), is reduced, and the reaction quotient for the dissolution of silver chloride, [Ag + ][Cl ], falls below the solubility product of AgCl:

    \[Q=\left[ \ce{Ag^{+}} \right]\left[ \ce{Cl^{-}} \right]<K_{ sp } \nonumber \]

    More silver chloride then dissolves. If the concentration of ammonia is great enough, all of the silver chloride dissolves.

    Example \(\PageIndex{1}\): Dissociation of a Complex Ion

    Calculate the concentration of the silver ion in a solution that initially is 0.10 M with respect to \(\ce{Ag(NH3)2^{+}}\)).

    Solution

    Applying the standard ICE approach to this reaction yields the following:

    This table has two main columns and four rows. The first row for the first column does not have a heading and then has the following in the first column: Initial concentration ( M ), Change ( M ), and Equilibrium concentration ( M ). The second column has the header, “A g superscript positive sign plus 2 N H subscript 3 equilibrium sign A g ( N H subscript 3 ) subscript 2 superscript positive sign.” Under the second column is a subgroup of three rows and three columns. The first column contains: 0, positive x, x. The second column contains: 0, positive 2 x, 2 x. The third column contains 0.10, negative x, and 0.10 minus x.

    Substituting these equilibrium concentration terms into the Kf expression gives

    \[\begin{align*}
    K_{ f } &=\dfrac{[ \ce{Ag(NH3)2^{+}} ]}{[ \ce{Ag^{+}} ][ \ce{NH3} ]^2} \\[4pt]
    1.7 \times 10^7 &=\frac{0.10-x}{(x)(2 x)^2}
    \end{align*} \nonumber \]

    The very large equilibrium constant means the amount of the complex ion that will dissociate, x, will be very small. Assuming \(x \ll 0.1\) permits simplifying the above equation:

    \[\begin{align*}
    1.7 \times 10^7 &=\frac{0.10}{(x)(2 x)^2} \\[4pt]
    x^3&=\frac{0.10}{4\left(1.7 \times 10^7\right)}=1.5 \times 10^{-9} \\[4pt]
    x&=\sqrt[3]{1.5 \times 10^{-9}}=1.1 \times 10^{-3}
    \end{align*} \nonumber \]

    Because only 1.1% of the \(\ce{Ag(NH3)2^{+}}\)) dissociates into \(\ce{Ag^{+}}\) and \(\ce{NH3}\), the assumption that x is small is justified.

    Using this value of x and the relations in the above ICE table allows calculation of all species’ equilibrium concentrations:

    \[\begin{align*}
    [ \ce{Ag^{+}} ] &=0+x=1.1 \times 10^{-3}~\text{M} \\[4pt]
    [ \ce{NH3}] &=0+2 x=2.2 \times 10^{-3} ~\text{M} \\[4pt]
    [ \ce{Ag(NH3)2^{+}}] &=0.10-x=0.10-0.0011 \\[4pt] &=0.099 ~\text{M}
    \end{align*} \nonumber \]

    The concentration of free silver ion in the solution is 0.0011 M.

    Exercise \(\PageIndex{1}\)

    Calculate the silver ion concentration, [Ag+], of a solution prepared by dissolving 1.00 g of \(\ce{AgNO3}\) and 10.0 g of \(\ce{KCN}\) in sufficient water to make 1.00 L of solution. (Hint: Because Kf is very large, assume the reaction goes to completion then calculate the [Ag+] produced by dissociation of the complex.)

    Answer

    \(2.9 \times 10^{–22} ~\text{M}\)


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