4.1 What are Acids and Bases?

Arrhenius Acids and Bases

The most common definition of an acid is a substance that ionizes in water to produce \(\ce{H+}\) (proton) (or more correctly, \(\ce{H3O+}\) hydronium ions), and a base is a substance that ionizes (or dissociates, in the case of an ionic base) in water to produce \(\ce{OH-}\) (hydroxide). This definition is attributed to Svante Arrhenius (Svante Arrhenius - Wikipedia).

Fig. 38 When hydrogen chloride (\(\ce{HCl}\)) gas dissolves in water, (a) it reacts as an acid, transferring protons to water molecules to yield (b) hydronium \(\ce{H3O+}\) ions (and solvated chloride ions). Image source: 7.2 Classifying Chemical Reactions - Chemistry: Atoms First | OpenStax

As shown in Fig. 38, \(\ce{HCl}\) reaction with water is essentially \(\pu{100 \%}\) efficient. Because every \(\ce{HCl}\) molecule that dissolves in water undergoes this reaction, such acids are called strong acids.

\[ \ce{HCl(aq) + H2O(aq)⟶ Cl−(aq) + H3O+(aq)} \]

A far greater number of compounds behave as weak acids and only partially react with water, leaving a large majority of dissolved molecules in their original form and generating a relatively small amount of hydronium ions. Weak acids are more commonly encountered in nature, partly responsible for the tangy taste of citrus fruits, the stinging sensation of insect bites, and the unpleasant smells associated with body odor. A familiar example of a weak acid is acetic acid (\(\ce{CH3COOH}\)), the main ingredient in vinegar:

\[ \ce{ CH3COOH(aq) + H2O(l) ⇌ CH3COO− (aq) + H3O+(aq) } \]

When dissolved in water under typical conditions, only about \(\pu{1 \%}\) of acetic acid molecules are present in the ionized form, \(\ce{CH3COO−}\). (The use of a double-arrow in the reaction above denotes the partial reaction aspect of this process, a concept addressed in the chapter on chemical equilibrium.)

A base is a substance that will dissolve in water to yield \(\ce{OH-}\). The most common bases are ionic compounds composed of alkali or alkaline earth metal cations (groups 1 and 2) combined with the \(\ce{OH-}\) - for example, \(\ce{NaOH}\) and \(\ce{Ca(OH)2}\). When these compounds dissolve in water, \(\ce{OH-}\) are released directly into the solution. These bases and other hydroxides that completely dissociate in water are considered strong bases. Consider as an example the dissolution of lye (sodium hydroxide) in water:

\[\ce{ NaOH(s) ⟶ Na+(aq) + OH−(aq) } \]

This reaction confirms that \(\ce{NaOH}\) is a base. Since dissociation is essentially complete when ionic compounds dissolve in water under typical conditions, NaOH and other ionic hydroxides are classified as strong bases.

Unlike ionic hydroxides, some compounds produce \(\ce{OH-}\) when dissolved by chemically reacting with water molecules. These compounds react only partially in all cases and are classified as weak bases. These compounds are also abundant in nature and important commodities in various technologies. For example, global production of the weak base ammonia is typically well over \(\pu{100 tons}\) annually, being widely used as an agricultural fertilizer, a raw material for chemical synthesis of other compounds, and an active ingredient in household cleaners. When dissolved in water, ammonia reacts partially to yield \(\ce{OH-}\), as shown here:

\[ \ce{ NH3(aq) + H2O(l) ⇌ NH4+(aq) + OH−(aq) }\]

This is, by definition, an acid-base reaction, in this case involving the transfer of \(\ce{H+}\) from water molecules to ammonia molecules. Under typical conditions, only about \(\pu{1 \%}\) of the dissolved ammonia is present as \(\ce{NH4+}\) ions.

Example: Arrhenius acids and bases

Identify the Arrhenius acids and bases in the reactions below:

\[\begin{split} \begin{align*} \ce{HCl &-> H+ + Cl- \\ HNO3 &-> H+ + NO3- \\ NaOH &-> Na+ + OH- \\ Ca(OH)2 &-> Ca^2+ + 2 OH-} \end{align*} \end{split}\]

The first two reactions are examples of an Arrhenius acid, while the third and fourth reactions are examples of an Arrhenius base.

Brønsted-Lowry Acids and Bases

The Arrhenius definition of acids and bases in the previous section is slightly restrictive. For example, this definition does not cover bases that do not produce \(\ce{OH-}\) (e.g., \(\ce{NH3}\) in the last reaction). Johannes Brønsted (Johannes Nicolaus Brønsted - Wikipedia) and Thomas Martin Lowry (Martin Lowry - Wikipedia) improved the standard definition as follows: Brønsted-Lowry acid is a proton (\(\ce{H+}\)) donor, and a Brønsted-Lowry base is a \(\ce{H+}\) acceptor.

Example: Brønsted acids and bases

Identify the Brønsted acids and bases in the reactions below:

\[\begin{split} \begin{align*} \ce{HF &<=> H+ + F-\\ NH3 + H2O &<=> NH4+ + OH-} \end{align*} \end{split}\]

The first example is both an Arrhenius and Brønsted acid as is donated. The second example is also both an Arrhenius and Brønsted base because it produces a \(\ce{OH-}\) and accepts a \(\ce{H+}\) (to become \(\ce{NH4+}\)).

The reactions below show the same reaction, but it is important to recognize that \(\ce{H+}\) does not exist as an isolated species in solution. Instead, it is hydrated just as other aqueous ions are. The positively charged proton is strongly attracted to the partial negative charge (\(\delta -\)) on the oxygen atom in a water molecule and forms the hydronium ion, \(\ce{H3O+}\).

\[\begin{split} \begin{align*} \ce{HF &<=> H+ + F-\\ HF + H2O &<=> H3O+ + F-} \end{align*} \end{split}\]

Both \(\ce{H3O+}\) and \(\ce{H+}\) are used interchangeably throughout the text, but they refer to the same aqueous species.

Note that acids and bases that donate one are called monoprotic acids or bases (most examples shown above), and those that can donate or accept multiple are referred to as multiprotic or polyprotic acids and bases. Examples of polyprotic acids and bases include \(\ce{H2SO4}\) (sulfuric acid), \(\ce{H3PO4}\) (phosphoric acid), \(\ce{Ba(OH)2}\) (barium hydroxide), etc.

When a Brønsted-Lowry acid donates a \(\ce{H+}\), what remains of the acid is known as a conjugate base. For example, in the ionization of \(\ce{HCl}\) in water,

\[\ce{ HCl + H2O -> H3O+ + Cl- }\]

\(\ce{HCl}\) is the Brønsted-Lowry acid, producing a \(\ce{Cl-}\), the conjugate base. In other words, \(\ce{HCl-Cl-}\) are called a conjugate acid-base pair.

When a Brønsted-Lowry base accepts a \(\ce{H+}\), the newly formed protonated species is a conjugate acid. For example, \(\ce{NH3}\) ionizes in water,

\[\ce{ NH3 + H2O <=> NH4+ + OH- }\]

\(\ce{NH3}\) accepts a \(\ce{H+}\) from water to become the ammonium ion (\(\ce{NH4+}\)). \(\ce{NH4+}\) is the conjugate acid of \(\ce{NH3}\).

Fig. 39 Ionization of \(\ce{H2O}\) and \(\ce{NH3}\) to form to form Brønsted-Lowry acid-base conjugate pairs. Image source: 14.1 Brønsted-Lowry Acids and Bases - Chemistry: Atoms First | OpenStax.

Lewis Acids and Bases

Some chemical substances behave similarly to acids and bases as defined above but do not involve the transfer of \(\ce{H+}\). In Lewis’s definition of acid-base behavior, acids and bases are identified by their ability to accept or donate a pair of electrons and form a coordinate covalent bond. A coordinate covalent 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.

Fig. 40 A coordinate covalent bond shows a water molecule combining with a hydrogen ion to form a hydronium ion, and an ammonia molecule combines with a hydrogen ion to form an ammonium ion. Image source: 15.2 Lewis Acids and Bases - Chemistry 2e | OpenStax

The species donating the electron pair that comprise 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 reaction. Brønsted-Lowry acid-base reactions represent a subcategory of Lewis acid reactions, specifically, those in which the acid species is \(\ce{H+}\).

For more information, see 15.2 Lewis Acids and Bases - Chemistry 2e | OpenStax

Acid-Base Properties of Water

Water is considered a universal solvent due to its ubiquity and importance for all biological, environmental, and surficial geological processes. In addition, most environmental acid-base chemistry occurs in aqueous solution. Water can act as either a Brønsted-Lowry acid (as in the ionization of \(\ce{HCl}\)) or a Brønsted-Lowry base (as in the ionization of \(\ce{NH3}\)). Amphoteric species can behave either as a Brønsted-Lowry acid or a Brønsted-Lowry base. Water is also a very weak electrolyte, but it does undergo ionization to a small extent:

\[\ce{ H2O <=> H+ + OH- }\]

This reaction is known as the autoionization of water. Because we can represent the aqueous proton as either \(\ce{H+}\) or \(\ce{H3O+}\), we can also write the autoionization of water as

\[\ce{ 2 H2O <=> H3O+ + OH- }\]

where one \(\ce{H2O}\) acts as an acid and the other acts as a base. As indicated by the \(\rightleftharpoons\) in the reaction above, this is an equilibrium reaction. We can use basic thermodynamic principles to estimate the \(K_c\) for this reaction. The equilibrium expression for the above reactions can be written as

(35)\[K_c = \dfrac{\{\ce{H3O+}\}\{\ce{OH-}\}}{\{\ce{H2O}\}^2} = \{\ce{H3O+}\}\{\ce{OH-}\} = K_w\]

Note that \(\{\ce{H2O}\}= 1\) by convention. Since this is an important equilibrium reaction encountered frequently in environmental systems, we give \(K_c\) a special subscript \(w\) to indicate the autoionization equilibrium constant of water, \(K_w\).

Using thermodynamic data, we can calculate \(K_w\) at \(\pu{25 ^\circ C}\) as

(36)\[K_w = \{\ce{H3O+}\}\{\ce{OH-}\} = \pu{e-14}\]

In pure water, autoionization is the only source of \(\ce{H3O+}\) and \(\ce{OH-}\), and the reaction’s stoichiometry tells us that their concentrations are equal. At \(\pu{25 ^\circ C}\),

\[\{\ce{H3O+}\} = \{\ce{OH-}\} = \pu{1.0e-7}\]

Concentrations of \(\ce{H3O+}\) and \(\ce{OH-}\) are usually so low in environmental systems compared with the remainder of ions that their activities are practically equal to their concentrations.

Although \(K_w\) is constant, the individual concentrations of \(\ce{H3O+}\) and \(\ce{OH-}\) can be influenced by adding an acid or a base. The relative amounts of \(\ce{H3O+}\) and \(\ce{OH-}\) determine whether a solution is neutral, acidic, or basic as summarized in Table 12

Table 12 Relative amounts of \(\ce{H3O+}\) and \(\ce{OH-}\) in aqueous solutions.

Acid or Base	\(\ce{H3O+}\) vs \(\ce{OH-}\)
Acid	\(\{\ce{H3O+}\} > \{\ce{OH-}\}\)
Neutral	\(\{\ce{H3O+}\} = \{\ce{OH-}\}\)
Base	\(\{\ce{H3O+}\} < \{\ce{OH-}\}\)

Example: Calculating \(\ce{H3O+}\) and \(\ce{OH-}\)

The acid concentration in the stomach (\(\{\ce{H3O+}\}) is \)\pu{0.1 M}\(. Calculate the \)\ce{OH-}\( in stomach acid at \)\pu{25 ^\circ C}$.

Let’s substitute \(\ce{H3O+}\) into Eq. (36).

\[\begin{split}\begin{aligned} K_w = \pu{1e-14} &= \{\ce{H3O+}\}\{\ce{OH-}\} = (0.1)\{\ce{OH-}\}\\ \therefore \, \{\ce{OH-}\} &= \frac{\pu{1e-14}}{0.1} =\pu{1.0e-13 M} \end{aligned}\end{split}\]

\(p\ce{H}\) and \(p\ce{OH}\)

The acidity of an aqueous solution depends on \(\{\ce{H3O+}\}\). This concentration can range over many orders of magnitude, making reporting the numbers cumbersome. To describe the acidity of a solution, rather than report the molar concentration of \(\ce{H3O+}\), we typically use the more convenient scale. The \(p\ce{H}\) of a solution is defined as the negative base-10 logarithm of the \(\{\ce{H3O+}\}\) (in \(\pu{mol L-1}\) or \(\pu{M}\)).

(37)\[p\ce{H} = -\log_{10}[\ce{H3O+}]\]

\(p\ce{H}\) of a solution is dimensionless, and concentration units are removed before applying the logarithm. Conversely, the original units are returned when solution concentration is calculated from \(p\ce{H}\).

Example: Calculating \(p\ce{H}\)

Calculate the \(p\ce{H}\) of pure water at \(\pu{25 ^\circ C}\).

From the previous section we know that \(\{\ce{H3O+}\} = \pu{1e-7 M}\). Therefore,

\[p\ce{H} = -\log_{10}(\pu{1e-7}) = 7.0 \]

Our understanding of \(\ce{H3O+}\) and \(\ce{OH-}\) in water can be summarized as shown in Table 13.

Table 13 Relative amounts of \(\ce{H3O+}\) and \(\ce{OH-}\) and the \(p\ce{H}\) in aqueous solutions.

Acid or Base	\(\ce{H3O+}\) vs \(\ce{OH-}\)	\(p\ce{H}\) range
Acid	\(\{\ce{H3O+}\} > \{\ce{OH-}\}\)	\(p\ce{H} < 7\)
Neutral	\(\{\ce{H3O+}\} = \{\ce{OH-}\}\)	\(p\ce{H} = 7\)
Base	\(\{\ce{H3O+}\} < \{\ce{OH-}\}\)	\(p\ce{H} > 7\)

We can also determine the concentration by using the “antilog” or “inverse log” as shown below:

(38)\[[\ce{H3O+}] = 10^{-p\ce{H}}\]

Let’s look at Eq. (36) again and apply a negative logarithm to both sides.

(39)\[\begin{split}\begin{aligned} -\log_{10}(\{\ce{H3O+}\}\{\ce{OH-}\}) &= -\log_{10}(\pu{1.0e-14}) \\ -\log_{10}(\{\ce{H3O+}\}) - \log_{10}(\{\ce{OH-}\}) &= 14 \\ p\ce{H} + p\ce{OH} &= 14 \end{aligned}\end{split}\]

Eq. (39) gives us another way to express \(\{\ce{H3O+}\}\) and \(\{\ce{OH-}\}\) in water.

For more information, see 14.2 pH and pOH - Chemistry: Atoms First | OpenStax