Alkali metals Aside from NaOH and KOH, which enjoy very large scale applications, the hydroxides of the other alkali metals also are useful.
Lithium hydroxide (LiOH) is used in
breathing gas purification systems for
spacecraft,
submarines, and
rebreathers to remove
carbon dioxide from exhaled gas. :2 LiOH + CO2 → Li2CO3 + H2O The hydroxide of lithium is preferred to that of sodium because of its lower mass.
Sodium hydroxide,
potassium hydroxide, and the hydroxides of the other
alkali metals are also
strong bases.
Alkaline earth metals Beryllium hydroxide Be(OH)2 is
amphoteric. The hydroxide itself is
insoluble in water, with a
solubility product log
K*sp of −11.7. Addition of acid gives soluble
hydrolysis products, including the trimeric ion [Be3(OH)3(H2O)6]3+, which has OH groups bridging between pairs of beryllium ions making a 6-membered ring. At very low pH the
aqua ion [Be(H2O)4]2+ is formed. Addition of hydroxide to Be(OH)2 gives the soluble tetrahydroxoberyllate or tetrahydroxido
beryllate anion, [Be(OH)4]2−. The solubility in water of the other hydroxides in this group increases with increasing
atomic number.
Magnesium hydroxide Mg(OH)2 is a strong base (up to the limit of its solubility, which is very low in pure water), as are the hydroxides of the heavier alkaline earths:
calcium hydroxide,
strontium hydroxide, and
barium hydroxide. A solution or suspension of calcium hydroxide is known as
limewater and can be used to test for the
weak acid carbon dioxide. The reaction Ca(OH)2 + CO2 Ca2+ + + OH− illustrates the basicity of calcium hydroxide.
Soda lime, which is a mixture of the strong bases NaOH and KOH with Ca(OH)2, is used as a CO2 absorbent.
Boron group elements The simplest hydroxide of boron B(OH)3, known as
boric acid, is an acid. Unlike the hydroxides of the alkali and alkaline earth hydroxides, it does not dissociate in aqueous solution. Instead, it reacts with water molecules acting as a Lewis acid, releasing protons. :B(OH)3 + H2O tetrahydroxyborate| + H+ A variety of
oxyanions of boron are known, which, in the protonated form, contain hydroxide groups.
Aluminium hydroxide Al(OH)3 is amphoteric and dissolves in alkaline solution. for the production of pure aluminium oxide from
bauxite minerals this equilibrium is manipulated by careful control of temperature and alkali concentration. In the first phase, aluminium dissolves in hot alkaline solution as , but other hydroxides usually present in the mineral, such as iron hydroxides, do not dissolve because they are not amphoteric. After removal of the insolubles, the so-called
red mud, pure aluminium hydroxide is made to precipitate by reducing the temperature and adding water to the extract, which, by diluting the alkali, lowers the pH of the solution. Basic aluminium hydroxide AlO(OH), which may be present in bauxite, is also amphoteric. In mildly acidic solutions, the hydroxo/hydroxido complexes formed by aluminium are somewhat different from those of boron, reflecting the greater size of Al(III) vs. B(III). The concentration of the species [Al13(OH)32]7+ is very dependent on the total aluminium concentration. Various other hydroxo complexes are found in crystalline compounds. Perhaps the most important is the basic hydroxide AlO(OH), a polymeric material known by the names of the mineral forms
boehmite or
diaspore, depending on crystal structure.
Gallium hydroxide,
Carbon group elements Carbon forms no simple hydroxides. The
hypothetical compound C(OH)4 (
orthocarbonic acid or methanetetrol) is unstable in aqueous solution: :C(OH)4 → + H3O+ : + H+ H2CO3 It has only been produced in the laboratory from carbon dioxide and water under extreme low temperatures and pressures with high-energy irradiation.
Silicic acid is the name given to a variety of compounds with a generic formula [SiO
x(OH)4−2
x]
n. Orthosilicic acid has been identified in very dilute aqueous solution. It is a weak acid with p
Ka1 = 9.84, p
Ka2 = 13.2 at 25 °C. It can be written as H4SiO4 or Si(OH)4. Tin(IV) hydroxide is unknown but can be regarded as the hypothetical acid from which
stannates, with a formula [Sn(OH)6]2−, are derived by reaction with the (Lewis) basic hydroxide ion. Hydrolysis of Pb2+ in aqueous solution is accompanied by the formation of various hydroxo-containing complexes, some of which are insoluble. The basic hydroxo complex [Pb6O(OH)6]4+ is a cluster of six lead centres with metal–metal bonds surrounding a central oxide ion. The six hydroxide groups lie on the faces of the two external Pb4 tetrahedra. In strongly alkaline solutions soluble
plumbate ions are formed, including [Pb(OH)6]2−.
Other main-group elements In the higher oxidation states of the
pnictogens,
chalcogens,
halogens, and
noble gases there are oxoacids in which the central atom is attached to oxide ions and hydroxide ions. Examples include
phosphoric acid H3PO4, and
sulfuric acid H2SO4. In these compounds one or more hydroxide groups can
dissociate with the liberation of hydrogen cations as in a standard
Brønsted–Lowry acid. Many oxoacids of sulfur are known and all feature OH groups that can dissociate.
Telluric acid is often written with the formula H2TeO4·2H2O but is better described structurally as Te(OH)6. Orthoperiodic acid can lose all its protons, eventually forming the periodate ion [IO4]−. It can also be protonated in strongly acidic conditions to give the octahedral ion [I(OH)6]+, completing the
isoelectronic series, [E(OH)6]
z, E = Sn, Sb, Te, I;
z = −2, −1, 0, +1. Other acids of iodine(VII) that contain hydroxide groups are known, in particular in salts such as the mesoperiodate ion that occurs in K4[I2O8(OH)2]·8H2O. As is common outside of the alkali metals, hydroxides of the elements in lower oxidation states are complicated. For example,
phosphorous acid H3PO3 predominantly has the structure OP(H)(OH)2, in equilibrium with a small amount of P(OH)3. The oxoacids of
chlorine,
bromine, and
iodine have the formula OA(OH), where
n is the
oxidation number: +1, +3, +5, or +7, and A = Cl, Br, or I. The only oxoacid of
fluorine is F(OH),
hypofluorous acid. When these acids are neutralized the hydrogen atom is removed from the hydroxide group.
Transition and post-transition metals The hydroxides of the
transition metals and
post-transition metals usually have the metal in the +2 (M = Mn, Fe, Co, Ni, Cu, Zn) or +3 (M = Fe, Ru, Rh, Ir) oxidation state. None are soluble in water, and many are poorly defined. One complicating feature of the hydroxides is their tendency to undergo further condensation to the oxides, a process called
olation. Hydroxides of metals in the +1 oxidation state are also poorly defined or unstable. For example,
silver hydroxide Ag(OH) decomposes spontaneously to the oxide (Ag2O). Copper(I) and gold(I) hydroxides are also unstable, although stable adducts of CuOH and AuOH are known. The polymeric compounds M(OH)2 and M(OH)3 are in general prepared by increasing the pH of an aqueous solution of the corresponding metal cation until the hydroxide
precipitates out of solution. On the converse, the hydroxides dissolve in acidic solution.
Zinc hydroxide Zn(OH)2 is amphoteric, forming the tetrahydroxido
zincate ion in strongly alkaline solution. ==Basic salts containing hydroxide==