Typical Acids and Bases

The properties of acids and bases result from differences between the chemistry of metals and nonmetals, as can be seen from the chemistry of these classes of compounds: hydrogne, oxides, and hydroxides.

Compounds that contain hydrogen bound to a nonmetal are called nonmetal hydrides. Because they contain hydrogen in the +1 oxidation state, these compounds can act as a source of the H⁺ ion in water.

Metal hydrides, on the other hand, contain hydrogen bound to a metal. Because these compounds contain hydrogen in a -1 oxidation state, they dissociate in water to give the H^- (or hydride) ion.

The H^- ion, with its pair of valence electrons, can abstract an H⁺ ion from a water molecule.

Since removing H⁺ ions from water molecules is one way to increase the OH^- ion concentration in a solution, metal hydrides are bases.

A similar pattern can be found in the chemistry of the oxides formed by metals and nonmetals. Nonmetal oxides dissolve in water to form acids. CO₂ dissolves in water to give carbonic acid, SO₃ gives sulfuric acid, and P₄O₁₀ reacts with water to give phosphoric acid.

Metal oxides, on the other hand, are bases. Metal oxides formally contain the O^2- ion, which reacts with water to give a pair of OH^- ions.

We see the same pattern in the chemistry of compounds that contain the

OH, or hydroxide, group. Metal hydroxides, such as LiOH, NaOH, KOH, and Ca(OH)₂, are bases.

The table below summarizes the trends observed in these three categories of compounds. Metal hydrides, metal oxides, and metal hydroxides are bases. Nonmetal hydrides, nonmetal oxides, and nonmetal hydroxides are acids.

Acids	Bases
Non-metal Hydrides HF, HCl, HBr, HCN, HSCN, H₂S	Metal Hydrides HI, LiH, NaH, KH, MgH₂, CaH₂
Non-metal Oxides CO₂, SO₂, SO₃, NO₂, P₄O₁₀	Metal Oxides Li₂O, Na₂O, K₂O, MgO, CaO
Non-metal Hydroxides HOCl, HONO₂, O₂S(OH)₂, OP(OH)₃	Metal Hydroxides LiOH, NaOH, KOH, Ca(OH)₂, Ba(OH)₂

The acidic hydrogen atoms in the non-metal hydroxides in the table above aren't bound to the nitrogen, sulfur, or phosphorus atoms. In each of these compounds, the acidic hydrogen is attached to an oxygen atom. These compounds are therefore all examples of oxyacids.

Skeleton structures for eight oxyacids are given in the figure below. As a general rule, acids that contain oxygen have skeleton structures in which the acidic hydrogens are attached to oxygen atoms.