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Hydroxide

February 15, 2024

Hydroxide is a diatomic anion with chemical formula OH. It consists of an oxygen and hydrogen atom held together by a single covalent bond, and carries a negative electric charge. It is an important but usually minor constituent of water. It functions as a base, a ligand, a nucleophile, and a catalyst. The hydroxide ion forms salts, some of which dissociate in aqueous solution, liberating solvated hydroxide ions. Sodium hydroxide is a multi-million-ton per annum commodity chemical. The corresponding electrically neutral compound HO is the hydroxyl radical. The corresponding covalently bound group –OH of atoms is the hydroxy group. Both the hydroxide ion and hydroxy group are nucleophiles and can act as catalysts in organic chemistry.

Hydroxide
Names
IUPAC name
Hydroxide
Systematic IUPAC name
Oxidanide (not recommended)
Identifiers
  • 14280-30-9
3D model (JSmol)
  • Interactive image
ChEBI
  • CHEBI:16234
ChemSpider
  • 936
  • 961
UNII
  • 9159UV381P
  • InChI=1S/H2O/h1H2/p-1
  • [OH-]
Properties
OH
Molar mass 17.007 g·mol−1
Conjugate acid Water
Conjugate base Oxide anion
Related compounds
Related compounds
 O2H+
OH
O22−
H2O
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

Many inorganic substances which bear the word hydroxide in their names are not ionic compounds of the hydroxide ion, but covalent compounds which contain hydroxy groups.

Hydroxide ion edit

The hydroxide ion is naturally produced from water by the self-ionization reaction:[1]

H3O+ + OH ⇌ 2H2O

The equilibrium constant for this reaction, defined as

Kw = [H+][OH][note 1]

has a value close to 10−14 at 25 °C, so the concentration of hydroxide ions in pure water is close to 10−7 mol∙dm−3, in order to satisfy the equal charge constraint. The pH of a solution is equal to the decimal cologarithm of the hydrogen cation concentration;[note 2] the pH of pure water is close to 7 at ambient temperatures. The concentration of hydroxide ions can be expressed in terms of pOH, which is close to (14 − pH),[note 3] so the pOH of pure water is also close to 7. Addition of a base to water will reduce the hydrogen cation concentration and therefore increase the hydroxide ion concentration (increase pH, decrease pOH) even if the base does not itself contain hydroxide. For example, ammonia solutions have a pH greater than 7 due to the reaction NH3 + H+NH+
4, which decreases the hydrogen cation concentration, which increases the hydroxide ion concentration. pOH can be kept at a nearly constant value with various buffer solutions.

 
Schematic representation of the bihydroxide ion[2]

In aqueous solution[3] the hydroxide ion is a base in the Brønsted–Lowry sense as it can accept a proton[note 4] from a Brønsted–Lowry acid to form a water molecule. It can also act as a Lewis base by donating a pair of electrons to a Lewis acid. In aqueous solution both hydrogen and hydroxide ions are strongly solvated, with hydrogen bonds between oxygen and hydrogen atoms. Indeed, the bihydroxide ion H
3O
2 has been characterized in the solid state. This compound is centrosymmetric and has a very short hydrogen bond (114.5 pm) that is similar to the length in the bifluoride ion HF
2 (114 pm).[2] In aqueous solution the hydroxide ion forms strong hydrogen bonds with water molecules. A consequence of this is that concentrated solutions of sodium hydroxide have high viscosity due to the formation of an extended network of hydrogen bonds as in hydrogen fluoride solutions.

In solution, exposed to air, the hydroxide ion reacts rapidly with atmospheric carbon dioxide, acting as an acid, to form, initially, the bicarbonate ion.

OH + CO2HCO
3

The equilibrium constant for this reaction can be specified either as a reaction with dissolved carbon dioxide or as a reaction with carbon dioxide gas (see Carbonic acid for values and details). At neutral or acid pH, the reaction is slow, but is catalyzed by the enzyme carbonic anhydrase, which effectively creates hydroxide ions at the active site.

Solutions containing the hydroxide ion attack glass. In this case, the silicates in glass are acting as acids. Basic hydroxides, whether solids or in solution, are stored in airtight plastic containers.

The hydroxide ion can function as a typical electron-pair donor ligand, forming such complexes as tetrahydroxoaluminate/tetrahydroxidoaluminate [Al(OH)4]. It is also often found in mixed-ligand complexes of the type [MLx(OH)y]z+, where L is a ligand. The hydroxide ion often serves as a bridging ligand, donating one pair of electrons to each of the atoms being bridged. As illustrated by [Pb2(OH)]3+, metal hydroxides are often written in a simplified format. It can even act as a 3-electron-pair donor, as in the tetramer [PtMe3(OH)]4.[4]

When bound to a strongly electron-withdrawing metal centre, hydroxide ligands tend to ionise into oxide ligands. For example, the bichromate ion [HCrO4] dissociates according to

[O3CrO–H] ⇌ [CrO4]2− + H+

with a pKa of about 5.9.[5]

Vibrational spectra edit

The infrared spectra of compounds containing the OH functional group have strong absorption bands in the region centered around 3500 cm−1.[6] The high frequency of molecular vibration is a consequence of the small mass of the hydrogen atom as compared to the mass of the oxygen atom, and this makes detection of hydroxyl groups by infrared spectroscopy relatively easy. A band due to an OH group tends to be sharp. However, the band width increases when the OH group is involved in hydrogen bonding. A water molecule has an HOH bending mode at about 1600 cm−1, so the absence of this band can be used to distinguish an OH group from a water molecule.

When the OH group is bound to a metal ion in a coordination complex, an M−OH bending mode can be observed. For example, in [Sn(OH)6]2− it occurs at 1065 cm−1. The bending mode for a bridging hydroxide tends to be at a lower frequency as in [(bipyridine)Cu(OH)2Cu(bipyridine)]2+ (955 cm−1).[7] M−OH stretching vibrations occur below about 600 cm−1. For example, the tetrahedral ion [Zn(OH)4]2− has bands at 470 cm−1 (Raman-active, polarized) and 420 cm−1 (infrared). The same ion has a (HO)–Zn–(OH) bending vibration at 300 cm−1.[8]

Applications edit

Sodium hydroxide solutions, also known as lye and caustic soda, are used in the manufacture of pulp and paper, textiles, drinking water, soaps and detergents, and as a drain cleaner. Worldwide production in 2004 was approximately 60 million tonnes.[9] The principal method of manufacture is the chloralkali process.

Solutions containing the hydroxide ion are generated when a salt of a weak acid is dissolved in water. Sodium carbonate is used as an alkali, for example, by virtue of the hydrolysis reaction

CO2−
3 + H2O ⇌ HCO
3 + OH       (pKa2= 10.33 at 25 °C and zero ionic strength)

Although the base strength of sodium carbonate solutions is lower than a concentrated sodium hydroxide solution, it has the advantage of being a solid. It is also manufactured on a vast scale (42 million tonnes in 2005) by the Solvay process.[10] An example of the use of sodium carbonate as an alkali is when washing soda (another name for sodium carbonate) acts on insoluble esters, such as triglycerides, commonly known as fats, to hydrolyze them and make them soluble.

Bauxite, a basic hydroxide of aluminium, is the principal ore from which the metal is manufactured.[11] Similarly, goethite (α-FeO(OH)) and lepidocrocite (γ-FeO(OH)), basic hydroxides of iron, are among the principal ores used for the manufacture of metallic iron.[12]

Inorganic hydroxides edit

Alkali metals edit

Aside from NaOH and KOH, which enjoy very large scale applications, the hydroxides of the other alkali metals also are useful. Lithium hydroxide is a strong base, with a pKb of −0.36.[13] Lithium hydroxide is used in breathing gas purification systems for spacecraft, submarines, and rebreathers to remove carbon dioxide from exhaled gas.[14]

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.[15]

Alkaline earth metals edit

 
Trimeric hydrolysis product of beryllium dication[note 5]
 
Beryllium hydrolysis as a function of pH
Water molecules attached to Be are omitted

Beryllium hydroxide Be(OH)2 is amphoteric.[16] 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.[17] 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 tetrahydroxidoberyllate anion, [Be(OH)4]2−.

The solubility in water of the other hydroxides in this group increases with increasing atomic number.[18] 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+ + HCO
3 + 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 edit

 
Aluminium hydrolysis as a function of pH. Water molecules attached to Al are omitted

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 ⇌ B(OH)
4 + H+

A variety of oxyanions of boron are known, which, in the protonated form, contain hydroxide groups.[19]

 
Tetrahydroxo-
aluminate(III) ion

Aluminium hydroxide Al(OH)3 is amphoteric and dissolves in alkaline solution.[16]

Al(OH)3 (solid) + OH (aq) ⇌ Al(OH)
4 (aq)

In the Bayer process[20] 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 Al(OH)
4, 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,[16] indium hydroxide, and thallium(III) hydroxide are also amphoteric. Thallium(I) hydroxide is a strong base.[21]

Carbon group elements edit

Carbon forms no simple hydroxides. The hypothetical compound C(OH)4 (orthocarbonic acid or methanetetrol) is unstable in aqueous solution:[22]

C(OH)4HCO
3 + H3O+
HCO
3 + H+ ⇌ H2CO3

Carbon dioxide is also known as carbonic anhydride, meaning that it forms by dehydration of carbonic acid H2CO3 (OC(OH)2).[23]

Silicic acid is the name given to a variety of compounds with a generic formula [SiOx(OH)4−2x]n.[24][25] Orthosilicic acid has been identified in very dilute aqueous solution. It is a weak acid with pKa1 = 9.84, pKa2 = 13.2 at 25 °C. It is usually written as H4SiO4, but the formula Si(OH)4 is generally accepted.[5][dubious discuss] Other silicic acids such as metasilicic acid (H2SiO3), disilicic acid (H2Si2O5), and pyrosilicic acid (H6Si2O7) have been characterized. These acids also have hydroxide groups attached to the silicon; the formulas suggest that these acids are protonated forms of polyoxyanions.

Few hydroxo complexes of germanium have been characterized. Tin(II) hydroxide Sn(OH)2 was prepared in anhydrous media. When tin(II) oxide is treated with alkali the pyramidal hydroxo complex Sn(OH)
3 is formed. When solutions containing this ion are acidified, the ion [Sn3(OH)4]2+ is formed together with some basic hydroxo complexes. The structure of [Sn3(OH)4]2+ has a triangle of tin atoms connected by bridging hydroxide groups.[26] 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.[27]

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−.[28]

Other main-group elements edit

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.[29]

Telluric acid is often written with the formula H2TeO4·2H2O but is better described structurally as Te(OH)6.[30]

Ortho-periodic acid[note 6] 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.[31]

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.[32][33]

The oxoacids of chlorine, bromine, and iodine have the formula On−1/2A(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.[34]

Transition and post-transition metals edit

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.[35] The polymeric compounds M(OH)2 and M(OH)3 are in general prepared by increasing the pH of an aqueous solutions of the corresponding metal cations 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 tetrahydroxidozincate ion Zn(OH)2−
4 in strongly alkaline solution.[16]

Numerous mixed ligand complexes of these metals with the hydroxide ion exist. In fact, these are in general better defined than the simpler derivatives. Many can be made by deprotonation of the corresponding metal aquo complex.

LnM(OH2) + B ⇌ LnM(OH) + BH+ (L = ligand, B = base)

Vanadic acid H3VO4 shows similarities with phosphoric acid H3PO4 though it has a much more complex vanadate oxoanion chemistry. Chromic acid H2CrO4, has similarities with sulfuric acid H2SO4; for example, both form acid salts A+[HMO4]. Some metals, e.g. V, Cr, Nb, Ta, Mo, W, tend to exist in high oxidation states. Rather than forming hydroxides in aqueous solution, they convert to oxo clusters by the process of olation, forming polyoxometalates.[36]

Basic salts containing hydroxide edit

In some cases, the products of partial hydrolysis of metal ion, described above, can be found in crystalline compounds. A striking example is found with zirconium(IV). Because of the high oxidation state, salts of Zr4+ are extensively hydrolyzed in water even at low pH. The compound originally formulated as ZrOCl2·8H2O was found to be the chloride salt of a tetrameric cation [Zr4(OH)8(H2O)16]8+ in which there is a square of Zr4+ ions with two hydroxide groups bridging between Zr atoms on each side of the square and with four water molecules attached to each Zr atom.[37]

The mineral malachite is a typical example of a basic carbonate. The formula, Cu2CO3(OH)2 shows that it is halfway between copper carbonate and copper hydroxide. Indeed, in the past the formula was written as CuCO3·Cu(OH)2. The crystal structure is made up of copper, carbonate and hydroxide ions.[37] The mineral atacamite is an example of a basic chloride. It has the formula, Cu2Cl(OH)3. In this case the composition is nearer to that of the hydroxide than that of the chloride CuCl2·3Cu(OH)2.[38] Copper forms hydroxyphosphate (libethenite), arsenate (olivenite), sulfate (brochantite), and nitrate compounds. White lead is a basic lead carbonate, (PbCO3)2·Pb(OH)2, which has been used as a white pigment because of its opaque quality, though its use is now restricted because it can be a source for lead poisoning.[37]

Structural chemistry edit

The hydroxide ion appears to rotate freely in crystals of the heavier alkali metal hydroxides at higher temperatures so as to present itself as a spherical ion, with an effective ionic radius of about 153 pm.[39] Thus, the high-temperature forms of KOH and NaOH have the sodium chloride structure,[40] which gradually freezes in a monoclinically distorted sodium chloride structure at temperatures below about 300 °C. The OH groups still rotate even at room temperature around their symmetry axes and, therefore, cannot be detected by X-ray diffraction.[41] The room-temperature form of NaOH has the thallium iodide structure. LiOH, however, has a layered structure, made up of tetrahedral Li(OH)4 and (OH)Li4 units.[39] This is consistent with the weakly basic character of LiOH in solution, indicating that the Li–OH bond has much covalent character.

The hydroxide ion displays cylindrical symmetry in hydroxides of divalent metals Ca, Cd, Mn, Fe, and Co. For example, magnesium hydroxide Mg(OH)2 (brucite) crystallizes with the cadmium iodide layer structure, with a kind of close-packing of magnesium and hydroxide ions.[39][42]

The amphoteric hydroxide Al(OH)3 has four major crystalline forms: gibbsite (most stable), bayerite, nordstrandite, and doyleite.[note 7] All these polymorphs are built up of double layers of hydroxide ions – the aluminium atoms on two-thirds of the octahedral holes between the two layers – and differ only in the stacking sequence of the layers.[43] The structures are similar to the brucite structure. However, whereas the brucite structure can be described as a close-packed structure in gibbsite the OH groups on the underside of one layer rest on the groups of the layer below. This arrangement led to the suggestion that there are directional bonds between OH groups in adjacent layers.[44] This is an unusual form of hydrogen bonding since the two hydroxide ion involved would be expected to point away from each other. The hydrogen atoms have been located by neutron diffraction experiments on α-AlO(OH) (diaspore). The O–H–O distance is very short, at 265 pm; the hydrogen is not equidistant between the oxygen atoms and the short OH bond makes an angle of 12° with the O–O line.[45] A similar type of hydrogen bond has been proposed for other amphoteric hydroxides, including Be(OH)2, Zn(OH)2, and Fe(OH)3.[39]

A number of mixed hydroxides are known with stoichiometry A3MIII(OH)6, A2MIV(OH)6, and AMV(OH)6. As the formula suggests these substances contain M(OH)6 octahedral structural units.[46] Layered double hydroxides may be represented by the formula [Mz+
1−xM3+
x(OH)
2]q+(Xn)
qn·yH
2O. Most commonly, z = 2, and M2+ = Ca2+, Mg2+, Mn2+, Fe2+, Co2+, Ni2+, Cu2+, or Zn2+; hence q = x.

In organic reactions edit

Potassium hydroxide and sodium hydroxide are two well-known reagents in organic chemistry.

Base catalysis edit

The hydroxide ion may act as a base catalyst.[47] The base abstracts a proton from a weak acid to give an intermediate that goes on to react with another reagent. Common substrates for proton abstraction are alcohols, phenols, amines, and carbon acids. The pKa value for dissociation of a C–H bond is extremely high, but the pKa alpha hydrogens of a carbonyl compound are about 3 log units lower. Typical pKa values are 16.7 for acetaldehyde and 19 for acetone.[48] Dissociation can occur in the presence of a suitable base.

RC(O)CH2R' + B ⇌ RC(O)CHR' + BH+

The base should have a pKa value not less than about 4 log units smaller, or the equilibrium will lie almost completely to the left.

The hydroxide ion by itself is not a strong enough base, but it can be converted in one by adding sodium hydroxide to ethanol

OH + EtOH ⇌ EtO + H2O

to produce the ethoxide ion. The pKa for self-dissociation of ethanol is about 16, so the alkoxide ion is a strong enough base.[49] The addition of an alcohol to an aldehyde to form a hemiacetal is an example of a reaction that can be catalyzed by the presence of hydroxide. Hydroxide can also act as a Lewis-base catalyst.[50]

As a nucleophilic reagent edit

 
Nucleophilic acyl substitution with an anionic nucleophile (Nu) and leaving group (L)

The hydroxide ion is intermediate in nucleophilicity between the fluoride ion F, and the amide ion NH
2.[51] Ester hydrolysis under alkaline conditions (also known as base hydrolysis)

R1C(O)OR2 + OH ⇌ R1CO(O)H + OR2 ⇌ R1CO2 + HOR2

is an example of a nucleophilic acyl substitution with the hydroxide ion acting as a nucleophile.[52]

Early methods for manufacturing soap treated triglycerides from animal fat (the ester) with lye.

Other cases where hydroxide can act as a nucleophilic reagent are amide hydrolysis, the Cannizzaro reaction, nucleophilic aliphatic substitution, nucleophilic aromatic substitution, and in elimination reactions. The reaction medium for KOH and NaOH is usually water but with a phase-transfer catalyst the hydroxide anion can be shuttled into an organic solvent as well, for example in the generation of the reactive intermediate dichlorocarbene.

Notes edit

  1. ^ [H+] denotes the concentration of hydrogen cations and [OH] the concentration of hydroxide ions
  2. ^ Strictly speaking pH is the cologarithm of the hydrogen cation activity
  3. ^ pOH signifies the minus the logarithm to base 10 of [OH], alternatively the logarithm of 1/[OH]
  4. ^ In this context proton is the term used for a solvated hydrogen cation
  5. ^ In aqueous solution the ligands L are water molecules, but they may be replaced by other ligands
  6. ^ The name is not derived from "period", but from "iodine": per-iodic acid (compare iodic acid, perchloric acid), and it is thus pronounced per-iodic /ˌpɜːrˈɒdɪk/ PUR-eye-OD-ik, and not as /ˌpɪərɪ-/ PEER-ee-.
  7. ^ Crystal structures are illustrated at Web mineral: Gibbsite, Bayerite, Norstrandite and Doyleite

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  41. ^ Jacobs, H.; Kockelkorn, J.; Tacke, Th. (1985). "Hydroxide des Natriums, Kaliums und Rubidiums: Einkristallzüchtung und röntgenographische Strukturbestimmung an der bei Raumtemperatur stabilen Modifikation". Zeitschrift für Anorganische und Allgemeine Chemie. 531 (12): 119. doi:10.1002/zaac.19855311217.
  42. ^ Enoki, Toshiaki; Tsujikawa, Ikuji (1975). "Magnetic Behaviours of a Random Magnet, NipMg1−p(OH)2". Journal of the Physical Society of Japan. 39 (2): 317. Bibcode:1975JPSJ...39..317E. doi:10.1143/JPSJ.39.317.
  43. ^ Athanasios K. Karamalidis, David A. Dzombak Surface Complexation Modeling: Gibbsite, John Wiley and Sons, 2010 ISBN 0-470-58768-7 pp. 15 ff
  44. ^ Bernal, J.D.; Megaw, H.D. (1935). "The Function of Hydrogen in Intermolecular Forces". Proc. R. Soc. A. 151 (873): 384–420. Bibcode:1935RSPSA.151..384B. doi:10.1098/rspa.1935.0157.
  45. ^ Wells, p. 557
  46. ^ Wells, p. 555
  47. ^ Hattori, H.; Misono, M.; Ono, Y., eds. (1994). Acid–Base catalysis II. Elsevier. ISBN 978-0-444-98655-9.
  48. ^ Ouellette, R.J. and Rawn, J.D. "Organic Chemistry" 1st Ed. Prentice-Hall, Inc., 1996: New Jersey. ISBN 0-02-390171-3.
  49. ^ Pine, S.H.; Hendrickson, J.B.; Cram, D.J.; Hammond, G.S. (1980). Organic chemistry. McGraw–Hill. p. 206. ISBN 978-0-07-050115-7.
  50. ^ Denmark, S.E.; Beutne, G.L. (2008). "Lewis Base Catalysis in Organic Synthesis". Angewandte Chemie International Edition. 47 (9): 1560–1638. doi:10.1002/anie.200604943. PMID 18236505.
  51. ^ Mullins, J. J. (2008). "Six Pillars of Organic Chemistry". J. Chem. Educ. 85 (1): 83. Bibcode:2008JChEd..85...83M. doi:10.1021/ed085p83.pdf 2011-07-07 at the Wayback Machine
  52. ^ Hardinger, Steven A. (2017). "Illustrated Glossary of Organic Chemistry: Saponification". Department of Chemistry & Biochemistry, UCLA. Retrieved April 10, 2023.

Bibliography edit

February 15, 2024
hydroxide, diatomic, anion, with, chemical, formula, consists, oxygen, hydrogen, atom, held, together, single, covalent, bond, carries, negative, electric, charge, important, usually, minor, constituent, water, functions, base, ligand, nucleophile, catalyst, h. Hydroxide is a diatomic anion with chemical formula OH It consists of an oxygen and hydrogen atom held together by a single covalent bond and carries a negative electric charge It is an important but usually minor constituent of water It functions as a base a ligand a nucleophile and a catalyst The hydroxide ion forms salts some of which dissociate in aqueous solution liberating solvated hydroxide ions Sodium hydroxide is a multi million ton per annum commodity chemical The corresponding electrically neutral compound HO is the hydroxyl radical The corresponding covalently bound group OH of atoms is the hydroxy group Both the hydroxide ion and hydroxy group are nucleophiles and can act as catalysts in organic chemistry Hydroxide NamesIUPAC name HydroxideSystematic IUPAC name Oxidanide not recommended IdentifiersCAS Number 14280 30 93D model JSmol Interactive imageChEBI CHEBI 16234ChemSpider 936PubChem CID 961UNII 9159UV381PInChI InChI 1S H2O h1H2 p 1SMILES OH PropertiesChemical formula OH Molar mass 17 007 g mol 1Conjugate acid WaterConjugate base Oxide anionRelated compoundsRelated compounds O2H OH O22 H2OExcept where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Infobox references Many inorganic substances which bear the word hydroxide in their names are not ionic compounds of the hydroxide ion but covalent compounds which contain hydroxy groups Contents 1 Hydroxide ion 1 1 Vibrational spectra 2 Applications 3 Inorganic hydroxides 3 1 Alkali metals 3 2 Alkaline earth metals 3 3 Boron group elements 3 4 Carbon group elements 3 5 Other main group elements 3 6 Transition and post transition metals 4 Basic salts containing hydroxide 5 Structural chemistry 6 In organic reactions 6 1 Base catalysis 6 2 As a nucleophilic reagent 7 Notes 8 References 9 BibliographyHydroxide ion editThe hydroxide ion is naturally produced from water by the self ionization reaction 1 H3O OH 2H2OThe equilibrium constant for this reaction defined as Kw H OH note 1 has a value close to 10 14 at 25 C so the concentration of hydroxide ions in pure water is close to 10 7 mol dm 3 in order to satisfy the equal charge constraint The pH of a solution is equal to the decimal cologarithm of the hydrogen cation concentration note 2 the pH of pure water is close to 7 at ambient temperatures The concentration of hydroxide ions can be expressed in terms of pOH which is close to 14 pH note 3 so the pOH of pure water is also close to 7 Addition of a base to water will reduce the hydrogen cation concentration and therefore increase the hydroxide ion concentration increase pH decrease pOH even if the base does not itself contain hydroxide For example ammonia solutions have a pH greater than 7 due to the reaction NH3 H NH 4 which decreases the hydrogen cation concentration which increases the hydroxide ion concentration pOH can be kept at a nearly constant value with various buffer solutions nbsp Schematic representation of the bihydroxide ion 2 In aqueous solution 3 the hydroxide ion is a base in the Bronsted Lowry sense as it can accept a proton note 4 from a Bronsted Lowry acid to form a water molecule It can also act as a Lewis base by donating a pair of electrons to a Lewis acid In aqueous solution both hydrogen and hydroxide ions are strongly solvated with hydrogen bonds between oxygen and hydrogen atoms Indeed the bihydroxide ion H3 O 2 has been characterized in the solid state This compound is centrosymmetric and has a very short hydrogen bond 114 5 pm that is similar to the length in the bifluoride ion HF 2 114 pm 2 In aqueous solution the hydroxide ion forms strong hydrogen bonds with water molecules A consequence of this is that concentrated solutions of sodium hydroxide have high viscosity due to the formation of an extended network of hydrogen bonds as in hydrogen fluoride solutions In solution exposed to air the hydroxide ion reacts rapidly with atmospheric carbon dioxide acting as an acid to form initially the bicarbonate ion OH CO2 HCO 3The equilibrium constant for this reaction can be specified either as a reaction with dissolved carbon dioxide or as a reaction with carbon dioxide gas see Carbonic acid for values and details At neutral or acid pH the reaction is slow but is catalyzed by the enzyme carbonic anhydrase which effectively creates hydroxide ions at the active site Solutions containing the hydroxide ion attack glass In this case the silicates in glass are acting as acids Basic hydroxides whether solids or in solution are stored in airtight plastic containers The hydroxide ion can function as a typical electron pair donor ligand forming such complexes as tetrahydroxoaluminate tetrahydroxidoaluminate Al OH 4 It is also often found in mixed ligand complexes of the type MLx OH y z where L is a ligand The hydroxide ion often serves as a bridging ligand donating one pair of electrons to each of the atoms being bridged As illustrated by Pb2 OH 3 metal hydroxides are often written in a simplified format It can even act as a 3 electron pair donor as in the tetramer PtMe3 OH 4 4 When bound to a strongly electron withdrawing metal centre hydroxide ligands tend to ionise into oxide ligands For example the bichromate ion HCrO4 dissociates according to O3CrO H CrO4 2 H with a pKa of about 5 9 5 Vibrational spectra edit The infrared spectra of compounds containing the OH functional group have strong absorption bands in the region centered around 3500 cm 1 6 The high frequency of molecular vibration is a consequence of the small mass of the hydrogen atom as compared to the mass of the oxygen atom and this makes detection of hydroxyl groups by infrared spectroscopy relatively easy A band due to an OH group tends to be sharp However the band width increases when the OH group is involved in hydrogen bonding A water molecule has an HOH bending mode at about 1600 cm 1 so the absence of this band can be used to distinguish an OH group from a water molecule When the OH group is bound to a metal ion in a coordination complex an M OH bending mode can be observed For example in Sn OH 6 2 it occurs at 1065 cm 1 The bending mode for a bridging hydroxide tends to be at a lower frequency as in bipyridine Cu OH 2Cu bipyridine 2 955 cm 1 7 M OH stretching vibrations occur below about 600 cm 1 For example the tetrahedral ion Zn OH 4 2 has bands at 470 cm 1 Raman active polarized and 420 cm 1 infrared The same ion has a HO Zn OH bending vibration at 300 cm 1 8 Applications editSodium hydroxide solutions also known as lye and caustic soda are used in the manufacture of pulp and paper textiles drinking water soaps and detergents and as a drain cleaner Worldwide production in 2004 was approximately 60 million tonnes 9 The principal method of manufacture is the chloralkali process Solutions containing the hydroxide ion are generated when a salt of a weak acid is dissolved in water Sodium carbonate is used as an alkali for example by virtue of the hydrolysis reaction CO2 3 H2O HCO 3 OH pKa2 10 33 at 25 C and zero ionic strength Although the base strength of sodium carbonate solutions is lower than a concentrated sodium hydroxide solution it has the advantage of being a solid It is also manufactured on a vast scale 42 million tonnes in 2005 by the Solvay process 10 An example of the use of sodium carbonate as an alkali is when washing soda another name for sodium carbonate acts on insoluble esters such as triglycerides commonly known as fats to hydrolyze them and make them soluble Bauxite a basic hydroxide of aluminium is the principal ore from which the metal is manufactured 11 Similarly goethite a FeO OH and lepidocrocite g FeO OH basic hydroxides of iron are among the principal ores used for the manufacture of metallic iron 12 Inorganic hydroxides editAlkali metals edit Aside from NaOH and KOH which enjoy very large scale applications the hydroxides of the other alkali metals also are useful Lithium hydroxide is a strong base with a pKb of 0 36 13 Lithium hydroxide is used in breathing gas purification systems for spacecraft submarines and rebreathers to remove carbon dioxide from exhaled gas 14 2 LiOH CO2 Li2CO3 H2OThe 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 15 Alkaline earth metals edit nbsp Trimeric hydrolysis product of beryllium dication note 5 nbsp Beryllium hydrolysis as a function of pHWater molecules attached to Be are omittedBeryllium hydroxide Be OH 2 is amphoteric 16 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 17 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 tetrahydroxidoberyllate anion Be OH 4 2 The solubility in water of the other hydroxides in this group increases with increasing atomic number 18 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 HCO 3 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 edit nbsp Aluminium hydrolysis as a function of pH Water molecules attached to Al are omittedThe 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 B OH 4 H A variety of oxyanions of boron are known which in the protonated form contain hydroxide groups 19 nbsp Tetrahydroxo aluminate III ionAluminium hydroxide Al OH 3 is amphoteric and dissolves in alkaline solution 16 Al OH 3 solid OH aq Al OH 4 aq In the Bayer process 20 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 Al OH 4 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 16 indium hydroxide and thallium III hydroxide are also amphoteric Thallium I hydroxide is a strong base 21 Carbon group elements edit Carbon forms no simple hydroxides The hypothetical compound C OH 4 orthocarbonic acid or methanetetrol is unstable in aqueous solution 22 C OH 4 HCO 3 H3O HCO 3 H H2CO3Carbon dioxide is also known as carbonic anhydride meaning that it forms by dehydration of carbonic acid H2CO3 OC OH 2 23 Silicic acid is the name given to a variety of compounds with a generic formula SiOx OH 4 2x n 24 25 Orthosilicic acid has been identified in very dilute aqueous solution It is a weak acid with pKa1 9 84 pKa2 13 2 at 25 C It is usually written as H4SiO4 but the formula Si OH 4 is generally accepted 5 dubious discuss Other silicic acids such as metasilicic acid H2SiO3 disilicic acid H2Si2O5 and pyrosilicic acid H6Si2O7 have been characterized These acids also have hydroxide groups attached to the silicon the formulas suggest that these acids are protonated forms of polyoxyanions Few hydroxo complexes of germanium have been characterized Tin II hydroxide Sn OH 2 was prepared in anhydrous media When tin II oxide is treated with alkali the pyramidal hydroxo complex Sn OH 3 is formed When solutions containing this ion are acidified the ion Sn3 OH 4 2 is formed together with some basic hydroxo complexes The structure of Sn3 OH 4 2 has a triangle of tin atoms connected by bridging hydroxide groups 26 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 27 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 28 Other main group elements edit nbsp nbsp nbsp nbsp nbsp nbsp Phosphorous acid Phosphoric acid Sulfuric acid Telluric acid Ortho periodic acid Xenic acidIn 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 Bronsted Lowry acid Many oxoacids of sulfur are known and all feature OH groups that can dissociate 29 Telluric acid is often written with the formula H2TeO4 2H2O but is better described structurally as Te OH 6 30 Ortho periodic acid note 6 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 31 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 32 33 The oxoacids of chlorine bromine and iodine have the formula On 1 2A 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 34 Transition and post transition metals edit 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 35 The polymeric compounds M OH 2 and M OH 3 are in general prepared by increasing the pH of an aqueous solutions of the corresponding metal cations 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 tetrahydroxidozincate ion Zn OH 2 4 in strongly alkaline solution 16 Numerous mixed ligand complexes of these metals with the hydroxide ion exist In fact these are in general better defined than the simpler derivatives Many can be made by deprotonation of the corresponding metal aquo complex LnM OH2 B LnM OH BH L ligand B base Vanadic acid H3VO4 shows similarities with phosphoric acid H3PO4 though it has a much more complex vanadate oxoanion chemistry Chromic acid H2CrO4 has similarities with sulfuric acid H2SO4 for example both form acid salts A HMO4 Some metals e g V Cr Nb Ta Mo W tend to exist in high oxidation states Rather than forming hydroxides in aqueous solution they convert to oxo clusters by the process of olation forming polyoxometalates 36 Basic salts containing hydroxide editIn some cases the products of partial hydrolysis of metal ion described above can be found in crystalline compounds A striking example is found with zirconium IV Because of the high oxidation state salts of Zr4 are extensively hydrolyzed in water even at low pH The compound originally formulated as ZrOCl2 8H2O was found to be the chloride salt of a tetrameric cation Zr4 OH 8 H2O 16 8 in which there is a square of Zr4 ions with two hydroxide groups bridging between Zr atoms on each side of the square and with four water molecules attached to each Zr atom 37 The mineral malachite is a typical example of a basic carbonate The formula Cu2CO3 OH 2 shows that it is halfway between copper carbonate and copper hydroxide Indeed in the past the formula was written as CuCO3 Cu OH 2 The crystal structure is made up of copper carbonate and hydroxide ions 37 The mineral atacamite is an example of a basic chloride It has the formula Cu2Cl OH 3 In this case the composition is nearer to that of the hydroxide than that of the chloride CuCl2 3Cu OH 2 38 Copper forms hydroxyphosphate libethenite arsenate olivenite sulfate brochantite and nitrate compounds White lead is a basic lead carbonate PbCO3 2 Pb OH 2 which has been used as a white pigment because of its opaque quality though its use is now restricted because it can be a source for lead poisoning 37 Structural chemistry editThe hydroxide ion appears to rotate freely in crystals of the heavier alkali metal hydroxides at higher temperatures so as to present itself as a spherical ion with an effective ionic radius of about 153 pm 39 Thus the high temperature forms of KOH and NaOH have the sodium chloride structure 40 which gradually freezes in a monoclinically distorted sodium chloride structure at temperatures below about 300 C The OH groups still rotate even at room temperature around their symmetry axes and therefore cannot be detected by X ray diffraction 41 The room temperature form of NaOH has the thallium iodide structure LiOH however has a layered structure made up of tetrahedral Li OH 4 and OH Li4 units 39 This is consistent with the weakly basic character of LiOH in solution indicating that the Li OH bond has much covalent character The hydroxide ion displays cylindrical symmetry in hydroxides of divalent metals Ca Cd Mn Fe and Co For example magnesium hydroxide Mg OH 2 brucite crystallizes with the cadmium iodide layer structure with a kind of close packing of magnesium and hydroxide ions 39 42 The amphoteric hydroxide Al OH 3 has four major crystalline forms gibbsite most stable bayerite nordstrandite and doyleite note 7 All these polymorphs are built up of double layers of hydroxide ions the aluminium atoms on two thirds of the octahedral holes between the two layers and differ only in the stacking sequence of the layers 43 The structures are similar to the brucite structure However whereas the brucite structure can be described as a close packed structure in gibbsite the OH groups on the underside of one layer rest on the groups of the layer below This arrangement led to the suggestion that there are directional bonds between OH groups in adjacent layers 44 This is an unusual form of hydrogen bonding since the two hydroxide ion involved would be expected to point away from each other The hydrogen atoms have been located by neutron diffraction experiments on a AlO OH diaspore The O H O distance is very short at 265 pm the hydrogen is not equidistant between the oxygen atoms and the short OH bond makes an angle of 12 with the O O line 45 A similar type of hydrogen bond has been proposed for other amphoteric hydroxides including Be OH 2 Zn OH 2 and Fe OH 3 39 A number of mixed hydroxides are known with stoichiometry A3MIII OH 6 A2MIV OH 6 and AMV OH 6 As the formula suggests these substances contain M OH 6 octahedral structural units 46 Layered double hydroxides may be represented by the formula Mz 1 x M3 x OH 2 q Xn q n yH2 O Most commonly z 2 and M2 Ca2 Mg2 Mn2 Fe2 Co2 Ni2 Cu2 or Zn2 hence q x In organic reactions editPotassium hydroxide and sodium hydroxide are two well known reagents in organic chemistry Base catalysis edit The hydroxide ion may act as a base catalyst 47 The base abstracts a proton from a weak acid to give an intermediate that goes on to react with another reagent Common substrates for proton abstraction are alcohols phenols amines and carbon acids The pKa value for dissociation of a C H bond is extremely high but the pKa alpha hydrogens of a carbonyl compound are about 3 log units lower Typical pKa values are 16 7 for acetaldehyde and 19 for acetone 48 Dissociation can occur in the presence of a suitable base RC O CH2R B RC O CH R BH The base should have a pKa value not less than about 4 log units smaller or the equilibrium will lie almost completely to the left The hydroxide ion by itself is not a strong enough base but it can be converted in one by adding sodium hydroxide to ethanol OH EtOH EtO H2Oto produce the ethoxide ion The pKa for self dissociation of ethanol is about 16 so the alkoxide ion is a strong enough base 49 The addition of an alcohol to an aldehyde to form a hemiacetal is an example of a reaction that can be catalyzed by the presence of hydroxide Hydroxide can also act as a Lewis base catalyst 50 As a nucleophilic reagent edit nbsp Nucleophilic acyl substitution with an anionic nucleophile Nu and leaving group L The hydroxide ion is intermediate in nucleophilicity between the fluoride ion F and the amide ion NH 2 51 Ester hydrolysis under alkaline conditions also known as base hydrolysis R1C O OR2 OH R1CO O H OR2 R1CO2 HOR2is an example of a nucleophilic acyl substitution with the hydroxide ion acting as a nucleophile 52 Early methods for manufacturing soap treated triglycerides from animal fat the ester with lye Other cases where hydroxide can act as a nucleophilic reagent are amide hydrolysis the Cannizzaro reaction nucleophilic aliphatic substitution nucleophilic aromatic substitution and in elimination reactions The reaction medium for KOH and NaOH is usually water but with a phase transfer catalyst the hydroxide anion can be shuttled into an organic solvent as well for example in the generation of the reactive intermediate dichlorocarbene Notes edit H denotes the concentration of hydrogen cations and OH the concentration of hydroxide ions Strictly speaking pH is the cologarithm of the hydrogen cation activity pOH signifies the minus the logarithm to base 10 of OH alternatively the logarithm of 1 OH In this context proton is the term used for a solvated hydrogen cation In aqueous solution the ligands L are water molecules but they may be replaced by other ligands The name is not derived from period but from iodine per iodic acid compare iodic acid perchloric acid and it is thus pronounced per iodic ˌ p ɜːr aɪ ˈ ɒ d ɪ k PUR eye OD ik and not as ˌ p ɪer ɪ PEER ee Crystal structures are illustrated at Web mineral Gibbsite Bayerite Norstrandite and DoyleiteReferences edit Geissler P L Dellago C Chandler D Hutter J Parrinello M 2001 Autoionization in liquid water PDF Science 291 5511 2121 2124 Bibcode 2001Sci 291 2121G CiteSeerX 10 1 1 6 4964 doi 10 1126 science 1056991 PMID 11251111 S2CID 1081091 Archived from the original PDF on 2007 06 25 Retrieved 2017 10 25 a b Kamal Abu Dari Kenneth N Raymond Derek P Freyberg 1979 The bihydroxide H3 O 2 anion A very short symmetric hydrogen bond J Am Chem Soc 101 13 3688 3689 doi 10 1021 ja00507a059 Marx D Chandra A Tuckerman M E 2010 Aqueous Basic Solutions Hydroxide Solvation Structural Diffusion and Comparison to the Hydrated Proton Chem Rev 110 4 2174 2216 doi 10 1021 cr900233f PMID 20170203 Greenwood p 1168 a b IUPAC SC Database Archived 2017 06 19 at the Wayback Machine A comprehensive database of published data on equilibrium constants of metal complexes and ligands Nakamoto K 1997 Infrared and Raman spectra of Inorganic and Coordination compounds Part A 5th ed Wiley ISBN 978 0 471 16394 7 Nakamoto Part B p 57 Adams D M 1967 Metal Ligand and Related Vibrations London Edward Arnold Chapter 5 Cetin Kurt Jurgen Bittner Sodium Hydroxide Ullmann s Encyclopedia of Industrial Chemistry Weinheim Wiley VCH doi 10 1002 14356007 a24 345 pub2 ISBN 978 3527306732 Kostick Dennis 2006 Soda Ash chapter in 2005 Minerals Yearbook United States Geological Survey Emsley John 2001 Aluminium Nature s Building Blocks An A Z Guide to the Elements Oxford UK Oxford University Press p 24 ISBN 978 0 19 850340 8 Emsley John 2001 Aluminium Nature s Building Blocks An A Z Guide to the Elements Oxford UK Oxford University Press p 209 ISBN 978 0 19 850340 8 Lew Kristi Acids and Bases Essential Chemistry Infobase Publishing 2009 p43 Jaunsen JR 1989 The Behavior and Capabilities of Lithium Hydroxide Carbon Dioxide Scrubbers in a Deep Sea Environment US Naval Academy Technical Report USNA TSPR 157 Archived from the original on 2009 08 24 Retrieved 2008 06 17 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint unfit URL link Holleman p 1108 a b c d Thomas R Dulski A manual for the chemical analysis of metals ASTM International 1996 ISBN 0 8031 2066 4 p 100 Alderighi L Dominguez S Gans P Midollini S Sabatini A Vacca A 2009 Beryllium binding to adenosine 5 phosphates in aqueous solution at 25 C J Coord Chem 62 1 14 22 doi 10 1080 00958970802474862 S2CID 93623985 Housecroft p 241 Housectroft p 263 Bayer process chemistry James E House Inorganic chemistry Academic Press 2008 ISBN 0 12 356786 6 p 764 Bohm Stanislav Antipova Diana Kuthan Josef 1997 A study of methanetetraol dehydration to carbonic acid International Journal of Quantum Chemistry 62 3 315 322 doi 10 1002 SICI 1097 461X 1997 62 3 lt 315 AID QUA10 gt 3 0 CO 2 8 ISSN 1097 461X Greenwood p 310 Greenwood p 346 R K Iler The Chemistry of Silica Wiley New York 1979 ISBN 0 471 02404 X Greenwood p 384 Greenwood pp 383 384 Greenwood p 395 Greenwood p 705 Greenwood p 781 Greenwood pp 873 874 M N Sokolov E V Chubarova K A Kovalenko I V Mironov A V Virovets E Peresypkina V P Fedin 2005 Stabilization of tautomeric forms P OH 3 and HP OH 2 and their derivatives by coordination to palladium and nickel atoms in heterometallic clusters with the Mo3 MQ4 4 core M Ni Pd Q S Se Russian Chemical Bulletin 54 3 615 doi 10 1007 s11172 005 0296 1 S2CID 93718865 Holleman pp 711 718 Greenwood p 853 Fortman George C Slawin Alexandra M Z Nolan Steven P 2010 A Versatile Cuprous Synthon Cu IPr OH IPr 1 3 bis diisopropylphenyl imidazol 2 ylidene Organometallics 29 17 3966 3972 doi 10 1021 om100733n Juan J Borras Almenar Eugenio Coronado Achim Muller Polyoxometalate Molecular Science Springer 2003 ISBN 1 4020 1242 X p 4 a b c Wells p 561 Wells p 393 a b c d Wells p 548 Victoria M Nield David A Keen Diffuse neutron scattering from crystalline materials Oxford University Press 2001 ISBN 0 19 851790 4 p 276 Jacobs H Kockelkorn J Tacke Th 1985 Hydroxide des Natriums Kaliums und Rubidiums Einkristallzuchtung und rontgenographische Strukturbestimmung an der bei Raumtemperatur stabilen Modifikation Zeitschrift fur Anorganische und Allgemeine Chemie 531 12 119 doi 10 1002 zaac 19855311217 Enoki Toshiaki Tsujikawa Ikuji 1975 Magnetic Behaviours of a Random Magnet NipMg1 p OH 2 Journal of the Physical Society of Japan 39 2 317 Bibcode 1975JPSJ 39 317E doi 10 1143 JPSJ 39 317 Athanasios K Karamalidis David A Dzombak Surface Complexation Modeling Gibbsite John Wiley and Sons 2010 ISBN 0 470 58768 7 pp 15 ff Bernal J D Megaw H D 1935 The Function of Hydrogen in Intermolecular Forces Proc R Soc A 151 873 384 420 Bibcode 1935RSPSA 151 384B doi 10 1098 rspa 1935 0157 Wells p 557 Wells p 555 Hattori H Misono M Ono Y eds 1994 Acid Base catalysis II Elsevier ISBN 978 0 444 98655 9 Ouellette R J and Rawn J D Organic Chemistry 1st Ed Prentice Hall Inc 1996 New Jersey ISBN 0 02 390171 3 Pine S H Hendrickson J B Cram D J Hammond G S 1980 Organic chemistry McGraw Hill p 206 ISBN 978 0 07 050115 7 Denmark S E Beutne G L 2008 Lewis Base Catalysis in Organic Synthesis Angewandte Chemie International Edition 47 9 1560 1638 doi 10 1002 anie 200604943 PMID 18236505 Mullins J J 2008 Six Pillars of Organic Chemistry J Chem Educ 85 1 83 Bibcode 2008JChEd 85 83M doi 10 1021 ed085p83 pdf Archived 2011 07 07 at the Wayback Machine Hardinger Steven A 2017 Illustrated Glossary of Organic Chemistry Saponification Department of Chemistry amp Biochemistry UCLA Retrieved April 10 2023 Bibliography editHolleman A F Wiberg E Wiberg N 2001 Inorganic Chemistry Academic press ISBN 978 0 12 352651 9 Housecroft C E Sharpe A G 2008 Inorganic Chemistry 3rd ed Prentice Hall ISBN 978 0 13 175553 6 Greenwood Norman N Earnshaw Alan 1997 Chemistry of the Elements 2nd ed Butterworth Heinemann ISBN 978 0 08 037941 8 Shriver D F Atkins P W 1999 Inorganic Chemistry 3rd ed Oxford Oxford University Press ISBN 978 0 19 850330 9 Wells A F 1962 Structural Inorganic Chemistry 3rd ed Oxford Clarendon Press ISBN 978 0 19 855125 6 Retrieved from https en wikipedia org w index php title Hydroxide amp oldid 1190624023, wikipedia, wiki, book, books, library,

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