Editing Coordination complex

{{Short description|Molecule or ion containing ligands datively bonded to a central metallic atom}}
[[File:Cisplatin-3D-balls.png|thumb|upright=1.2|[[Cisplatin]], PtCl<sub>2</sub>(NH<sub>3</sub>)<sub>2</sub>, is a coordination complex of platinum(II) with two chloride and two ammonia [[ligand]]s. It is one of the most successful anticancer drugs. (Cl=green, Pt=dark blue, N=blue, H=white)]]

A '''coordination complex''' is a chemical compound consisting of a central [[atom]] or [[ion]], which is usually [[metal]]lic and is called the ''coordination centre'', and a surrounding array of [[chemical bond|bound]] [[molecules]] or ions, that are in turn known as ''[[ligand]]s'' or complexing agents.<ref>{{cite book |title= Introduction to Coordination Chemistry |first= Geoffrey A. |last= Lawrance |year= 2010 |publisher= Wiley |isbn= 9780470687123 |doi= 10.1002/9780470687123}}</ref><ref>{{GoldBookRef | title = complex | file = C01203}}</ref><ref>{{GoldBookRef | file = C01330 | title = coordination entity}}</ref>  Many metal-containing [[chemical compound|compounds]], especially those that include [[transition metal]]s (elements like [[titanium]] that belong to the periodic table's [[d-block]]), are coordination complexes.<ref>{{Greenwood&Earnshaw2nd}}</ref>

==Nomenclature and terminology==
Coordination complexes are so pervasive that their structures and reactions are described in many ways, sometimes confusingly.  The atom within a ligand that is bonded to the central metal atom or ion is called the '''donor atom'''.  In a typical complex, a metal ion is bonded to several donor atoms, which can be the same or different. A [[Ligand#Polydentate and polyhapto ligand motifs and nomenclature|polydentate]] (multiple bonded) ligand is a molecule or ion that bonds to the central atom through several of the ligand's atoms; ligands with 2, 3, 4 or even 6 bonds to the central atom are common. These complexes are called [[chelate complex]]es; the formation of such complexes is called chelation, complexation, and coordination.

The central atom or ion, together with all ligands, comprise the [[coordination sphere]].<ref>{{cite news |url= http://www.chemistry-dictionary.com/definition/coordination+sphere.php |title= Definition of coordination sphere |newspaper= chemistry-dictionary.com }}</ref><ref>{{cite web |url= http://www.chem.purdue.edu/gchelp/cchem/whatis.html |title= What Is A Coordination Compound? |publisher= Purdue University Department of Chemistry }}</ref>  The central atoms or ion and the donor atoms comprise the first coordination sphere.

'''Coordination''' refers to the "coordinate covalent bonds" ([[dipolar bond]]s) between the ligands and the central atom. Originally, a complex implied a reversible association of [[molecule]]s, [[atom]]s, or [[ion]]s through such weak [[chemical bond]]s. As applied to coordination chemistry, this meaning has evolved. Some metal complexes are formed virtually irreversibly and many are bound together by bonds that are quite strong.<ref>{{Cite book|isbn=978-0-471-19957-1 |page=1355|last=Cotton|first=Frank Albert|author2=Geoffrey Wilkinson |author3=Carlos A. Murillo |title=Advanced Inorganic Chemistry|year=1999|publisher=John Wiley & Sons }}</ref><ref>{{Cite book|isbn=978-0-13-841891-5 |page=642|last=Miessler|first=Gary L.|author2=Donald Arthur Tarr|title=Inorganic Chemistry|year=1999|publisher=Prentice Hall }}</ref>

The number of donor atoms attached to the central atom or ion is called the [[coordination number]]. The most common coordination numbers are 2, 4, and especially 6. A hydrated ion is one kind of a complex ion (or simply a complex), a species formed between a central metal ion and one or more surrounding ligands, molecules or ions that contain at least one lone pair of electrons.

If all the ligands are [[Denticity|monodentate]], then the number of donor atoms equals the number of ligands. For example, the cobalt(II) hexahydrate ion or the hexaaquacobalt(II) ion&nbsp;[Co(H<sub>2</sub>O)<sub>6</sub>]<sup>2+</sup> is a hydrated-complex ion that consists of six water molecules attached to a metal ion&nbsp;Co. The oxidation state and the coordination number reflect the number of bonds formed between the metal ion and the ligands in the complex ion. However, the coordination number of&nbsp;Pt([[Ethylenediamine|en]]){{su|b=2|p=2+}} is 4 (rather than 2) since it has two bidentate ligands, which contain four donor atoms in total.

Any donor atom will give a pair of electrons. There are some donor atoms or groups which can offer more than one pair of electrons. Such are called bidentate (offers two pairs of electrons) or polydentate (offers more than two pairs of electrons). In some cases an atom or a group offers a pair of electrons to two similar or different central metal atoms or acceptors—by division of the electron pair—into a [[three-center two-electron bond]]. These are called bridging ligands.

==History==
[[File:Alfred Werner ETH-Bib Portr 09965.jpg|thumb|upright|[[Alfred Werner]]]]
Coordination complexes have been known since the beginning of modern chemistry. Early well-known coordination complexes include dyes such as [[Prussian blue]]. Their properties were first well understood in the late 1800s, following the 1869 work of [[Christian Wilhelm Blomstrand]]. Blomstrand developed what has come to be known as the ''complex ion chain theory.'' In considering metal amine complexes, he theorized that the ammonia molecules compensated for the charge of the ion by forming chains of the type [(NH<sub>3</sub>)<sub>X</sub>]<sup>X+</sup>, where  X is the coordination number of the metal ion. He compared his theoretical ammonia chains to hydrocarbons of the form (CH<sub>2</sub>)<sub>X</sub>.<ref>{{Cite web|title=Coordination compound - History of coordination compounds|url=https://www.britannica.com/science/coordination-compound|access-date=2021-07-07|website=Encyclopedia Britannica|language=en}}</ref>

Following this theory, Danish scientist [[Sophus Mads Jørgensen]] made improvements to it. In his version of the theory, Jørgensen claimed that when a molecule dissociates in a solution there were two possible outcomes: the ions would bind via the ammonia chains Blomstrand had described or the ions would bind directly to the metal.

It was not until 1893 that the most widely accepted version of the theory today was published by [[Alfred Werner]]. Werner's work included two important changes to the Blomstrand theory. The first was that Werner described the two possibilities in terms of location in the coordination sphere. He claimed that if the ions were to form a chain, this would occur outside of the coordination sphere while the ions that bound directly to the metal would do so within the coordination sphere.<ref>{{Cite web|url = https://www.britannica.com/EBchecked/topic/136410/coordination-compound|title = Coordination Compound}}</ref> In one of his most important discoveries however Werner disproved the majority of the chain theory. Werner discovered the spatial arrangements of the ligands that were involved in the formation of the complex hexacoordinate cobalt. His theory allows one to understand the difference between a coordinated ligand and a charge balancing ion in a compound, for example the chloride ion in the cobaltammine chlorides and to explain many of the previously inexplicable isomers.

In 1911, Werner first resolved the coordination complex [[hexol]] into [[Enantiomer|optical isomers]], overthrowing the theory that only carbon compounds could possess [[Chirality (chemistry)|chirality]].<ref>{{Cite journal|last=Werner|first=A.|date=May 1911|title=Zur Kenntnis des asymmetrischen Kobaltatoms. I|url=http://doi.wiley.com/10.1002/cber.19110440297|journal=Berichte der Deutschen Chemischen Gesellschaft|language=de|volume=44|issue=2|pages=1887–1898|doi=10.1002/cber.19110440297}}</ref>

==Structures==
[[File:Hexol-2D-wedged.png|thumb|Structure of hexol]]
The ions or molecules surrounding the central atom are called [[ligand]]s. Ligands are classified as [[ligand#Classification of ligands as L and X|L or X]] (or a combination thereof), depending on how many electrons they provide for the bond between ligand and central atom. L ligands provide two electrons from a [[lone pair|lone electron pair]], resulting in a [[coordinate covalent bond]]. X ligands provide one electron, with the central atom providing the other electron, thus forming a regular [[covalent bond]]. The ligands are said to be '''coordinated''' to the atom. For [[alkene]]s, the [[pi bond]]s can coordinate to metal atoms. An example is [[ethylene]] in the complex {{chem2|[PtCl3(C2H4)]-}} ([[Zeise's salt]]).

===Geometry===
In coordination chemistry, a structure is first described by its [[coordination number]], the number of ligands attached to the metal (more specifically, the number of donor atoms). Usually one can count the ligands attached, but sometimes even the counting can become ambiguous. Coordination numbers are normally between two and nine, but large numbers of ligands are not uncommon for the lanthanides and actinides. The number of bonds depends on the size, charge, and [[electron configuration]] of the metal ion and the ligands. Metal ions may have more than one coordination number.

Typically the chemistry of transition metal complexes is dominated by interactions between s and p [[molecular orbital]]s of the donor-atoms in the ligands and the d orbitals of the metal ions.  The s, p, and d orbitals of the metal can accommodate 18 electrons (see [[18-Electron rule]]). The maximum coordination number for a certain metal is thus related to the electronic configuration of the metal ion (to be more specific, the number of empty orbitals) and to the ratio of the size of the ligands and the metal ion. Large metals and small ligands lead to high coordination numbers, e.g. {{chem2|[Mo(CN)8](4-)}}. Small metals with large ligands lead to low coordination numbers, e.g. {{chem2|Pt[P(CMe3)]2}}. Due to their large size, [[lanthanide]]s, [[actinide]]s, and early transition metals tend to have high coordination numbers.

Most structures follow the points-on-a-sphere pattern (or, as if the central atom were in the middle of a [[polyhedron]] where the corners of that shape are the locations of the ligands), where orbital overlap (between ligand and metal orbitals) and ligand-ligand repulsions tend to lead to certain regular geometries. The most observed geometries are listed below, but there are many cases that deviate from a regular geometry, e.g. due to the use of ligands of diverse types (which results in irregular bond lengths; the coordination atoms do not follow a points-on-a-sphere pattern), due to the size of ligands, or due to [[electronic effect]]s (see, e.g., [[Jahn–Teller distortion]]):

*[[Linear molecular geometry|Linear]] for two-coordination
*[[Trigonal planar molecular geometry|Trigonal planar]] for three-coordination
*[[Tetrahedral molecular geometry|Tetrahedral]] or [[square planar molecular geometry|square planar]] for four-coordination
*[[Trigonal bipyramid molecular geometry|Trigonal bipyramidal]] for five-coordination
*[[Octahedral molecular geometry|Octahedral]] for six-coordination
*[[Pentagonal bipyramidal molecular geometry|Pentagonal bipyramidal]] for seven-coordination
*[[Square antiprismatic molecular geometry|Square antiprismatic]] for eight-coordination
*[[Tricapped trigonal prismatic molecular geometry|Tricapped trigonal prismatic]] for nine-coordination

The idealized descriptions of 5-, 7-, 8-, and 9- coordination are often indistinct geometrically from alternative structures with slightly differing L-M-L (ligand-metal-ligand) angles, e.g. the difference between square pyramidal and trigonal bipyramidal structures.<ref>Wells A.F. (1984) ''Structural Inorganic Chemistry'' 5th edition Oxford Science Publications {{ISBN|0-19-855370-6}}</ref>

*[[Square pyramidal molecular geometry|Square pyramidal]] for five-coordination<ref>{{cite journal
| title = Transition metal pentacoordination
|author1=Angelo R. Rossi |author2=Roald. Hoffmann | journal = [[Inorganic Chemistry (journal)|Inorganic Chemistry]]
| year = 1975
| volume = 14
| issue = 2
| pages = 365–374
| doi = 10.1021/ic50144a032
}}</ref>
* [[Capped octahedral molecular geometry|Capped octahedral]] or [[Capped trigonal prismatic molecular geometry|capped trigonal prismatic]] for seven-coordination<ref>{{cite journal
| title = Seven-coordination. A molecular orbital exploration of structure, stereochemistry, and reaction dynamics
|author1=Roald. Hoffmann |author2=Barbara F. Beier |author3=Earl L. Muetterties |author4=Angelo R. Rossi | journal = [[Inorganic Chemistry (journal)|Inorganic Chemistry]]
| year = 1977
| volume = 16
| issue = 3
| pages = 511–522
| doi = 10.1021/ic50169a002
}}</ref>
* [[Dodecahedral molecular geometry|Dodecahedral]] or [[Bicapped trigonal prismatic molecular geometry|bicapped trigonal prismatic]] for eight-coordination<ref>{{cite journal
| title   = Eight-Coordination
| author1 = Jeremy K. Burdett
| author2 =  Roald Hoffmann
| author3 =  Robert C. Fay
| journal = [[Inorganic Chemistry (journal)|Inorganic Chemistry]]
| year    = 1978
| volume  = 17
| issue   = 9
| pages   = 2553–2568
| doi     = 10.1021/ic50187a041
}}</ref>
*[[Capped square antiprismatic molecular geometry|Capped square antiprismatic]] for nine-coordination

To distinguish between the alternative coordinations for five-coordinated complexes, the [[Geometry index|τ geometry index]] was invented by Addison et al.<ref>{{cite journal |last1 = Addison |first1 = A. W. |last2 = Rao |first2 = N. T. |last3 = Reedijk |first3 = J. |last4 = van Rijn |first4 = J. |last5 = Verschoor |first5 = G. C. |year = 1984 |title = Synthesis, structure, and spectroscopic properties of copper(II) compounds containing nitrogen–sulphur donor ligands; the crystal and molecular structure of aqua[1,7-bis(''N''-methylbenzimidazol-2′-yl)-2,6-dithiaheptane]copper(II) perchlorate |journal = J. Chem. Soc., Dalton Trans. |issue = 7 |pages = 1349–1356 |doi = 10.1039/dt9840001349}}</ref> This index depends on angles by the coordination center and changes between 0 for the square pyramidal to 1 for trigonal bipyramidal structures, allowing to classify the cases in between. This system was later extended to four-coordinated complexes by Houser et al.<ref>{{cite journal |last1 = Yang |first1 = L. |last2 = Powell |first2 = D. R. |last3 = Houser |first3 = R. P. |year = 2007 |title = Structural variation in copper(I) complexes with pyridylmethylamide ligands: structural analysis with a new four-coordinate geometry index, {{math|''τ''{{sub|4}}}} |journal = Dalton Trans. |issue = 9 |pages = 955–64 |doi = 10.1039/b617136b|pmid = 17308676 }}</ref> and also Okuniewski et al.<ref>{{cite journal |last1 = Okuniewski |first1 = A. |last2 = Rosiak |first2 = D. |last3 = Chojnacki |first3 = J. |last4 = Becker |first4 = B. |year = 2015 |title = Coordination polymers and molecular structures among complexes of mercury(II) halides with selected 1-benzoylthioureas |journal = Polyhedron |volume = 90 |pages = 47–57 |doi = 10.1016/j.poly.2015.01.035}}</ref>

In systems with low [[d electron count]], due to special electronic effects such as (second-order) [[Jahn–Teller effect|Jahn–Teller]] stabilization,<ref>{{cite journal | title = "Non-VSEPR" Structures and Bonding in d<sup>0</sup> Systems | first = Martin | last = Kaupp | journal = [[Angewandte Chemie|Angew. Chem. Int. Ed. Engl.]] | year = 2001 | volume = 40 | issue = 1 | pages = 3534–3565 | doi =  10.1002/1521-3773(20011001)40:19<3534::AID-ANIE3534>3.0.CO;2-#| pmid = 11592184 }}</ref> certain geometries (in which the coordination atoms do not follow a points-on-a-sphere pattern) are stabilized relative to the other possibilities, e.g. for some compounds the trigonal prismatic geometry is stabilized relative to octahedral structures for six-coordination.

*[[Bent molecular geometry|Bent]] for two-coordination
*[[Trigonal pyramidal molecular geometry|Trigonal pyramidal]] for three-coordination
*[[Trigonal prismatic molecular geometry|Trigonal prismatic]] for six-coordination

===Isomerism===
The arrangement of the ligands is fixed for a given complex, but in some cases it is mutable by a reaction that forms another stable [[isomer]].

There exist many kinds of [[isomerism]] in coordination complexes, just as in many other compounds.

====Stereoisomerism====
[[Stereoisomerism]] occurs with the same bonds in distinct orientations. Stereoisomerism can be further classified into:<ref>von Zelewsky, A. "Stereochemistry of Coordination Compounds" John Wiley: Chichester, 1995. {{ISBN|0-471-95599-X}}.</ref>

=====Cis–trans isomerism and facial–meridional isomerism=====
[[Cis–trans isomerism]] occurs in octahedral and [[square planar]] complexes (but not tetrahedral). When two ligands are adjacent they are said to be '''cis''', when
opposite each other, '''trans'''. When three identical ligands occupy one face of an octahedron, the isomer is said to be facial, or '''fac'''. In a ''fac'' isomer, any two  identical ligands are adjacent or ''cis'' to each other. If these three ligands and the metal ion are in one plane, the isomer is said to be meridional, or '''mer'''. A ''mer'' isomer can be considered as a combination of a ''trans'' and a ''cis'', since it contains both trans and cis pairs of identical ligands.

<div align="center">
<gallery>
Image:Cis-dichlorotetraamminecobalt(III).png|{{chem2|''cis''\-[CoCl2(NH3)4]+}}
Image:Trans-dichlorotetraamminecobalt(III).png|{{chem2|''trans''\-[CoCl2(NH3)4]+}}
Image:Fac-trichlorotriamminecobalt(III).png|{{chem2|''fac''\-[CoCl3(NH3)3]}}
Image:Mer-trichlorotriamminecobalt(III).png|{{chem2|''mer''\-[CoCl3(NH3)3]}}
</gallery>
</div>

=====Optical isomerism=====
[[Optical isomerism]] occurs when a complex is not superimposable with its mirror image.  It is so called because the two isomers are each [[optically active]], that is, they rotate the plane of [[polarized light]] in opposite directions. In the first molecule shown, the symbol Λ (''[[lambda]]'') is used as a prefix to describe the left-handed propeller twist formed by three bidentate ligands.  The second molecule is the mirror image of the first, with the symbol Δ (''[[delta (letter)|delta]]'') as a prefix for the right-handed propeller twist. The third and fourth molecules are a similar pair of Λ and Δ isomers, in this case with two bidentate ligands and two identical monodentate ligands.<ref>{{Cite book|isbn=978-0-13-841891-5 |last=Miessler|first=Gary L.|author2=Donald Arthur Tarr|title=Inorganic Chemistry|year=1999|pages=315, 316|chapter=9|publisher=Prentice Hall }}</ref>

<div align="center">
<gallery>
Image:Delta-tris(oxalato)ferrate(III)-3D-balls.png|[[Potassium ferrioxalate|{{chem2|Λ\-[Fe(ox)3](3-)}}]]
Image:Lambda-tris(oxalato)ferrate(III)-3D-balls.png|{{chem2|Δ\-[Fe(ox)3](3-)}}
Image:Delta-cis-dichlorobis(ethylenediamine)cobalt(III).png|[[cis-Dichlorobis(ethylenediamine)cobalt(III) chloride|{{chem2|Λ\-''cis''\-[CoCl2(en)2]+}}]]
Image:Lambda-cis-dichlorobis(ethylenediamine)cobalt(III).png|{{chem2|Δ\-''cis''\-[CoCl2(en)2]+}}
</gallery>
</div>

====Structural isomerism====
[[Structural isomerism]] occurs when the bonds are themselves different. Four types of structural isomerism are recognized: ionisation isomerism, solvate or hydrate isomerism, linkage isomerism and coordination isomerism.
# '''Ionisation isomerism''' – the isomers give different ions in solution although they have the same composition. This type of isomerism occurs when the counter ion of the complex is also a potential ligand. For example, pentaamminebromocobalt(III) sulphate {{chem2|[Co(NH3)5Br]SO4}} is red violet and in solution gives a precipitate with barium chloride, confirming the presence of sulphate ion, while pentaamminesulphatecobalt(III) bromide {{chem2|[Co(NH3)5SO4]Br}} is red and tests negative for sulphate ion in solution, but instead gives a precipitate of AgBr with silver nitrate.<ref name=Huheey>Huheey, James E., ''Inorganic Chemistry'' (3rd ed., Harper & Row 1983), p.524–5 {{ISBN|0-06-042987-9}}</ref>
# [[Hydration isomerism|Solvate or hydrate isomerism]] – the isomers have the same composition but differ with respect to the number of molecules of solvent that serve as ligand vs simply occupying sites in the crystal. Examples: {{chem2|[Cr(H2O)6]Cl3}} is violet colored, {{chem2|[CrCl(H2O)5]Cl2·H2O}} is blue-green, and {{chem2|[CrCl2(H2O)4]Cl*2H2O}} is dark green. See [[water of crystallization]].<ref name=Huheey/>
# '''[[Linkage isomerism]]''' occurs with ligands with more than one possible donor atom, known as [[ambidentate ligand]]s.<ref name=Jolly>{{cite book |last1=Jolly |first1=William L. |title=Modern Inorganic Chemistry |date=1984 |publisher=McGraw-Hill |isbn=0-07-032760-2 |pages=357–9}}</ref> For example, [[nitrite]] can coordinate through O or N.<ref>Huheey, James E., ''Inorganic Chemistry'' (3rd ed., Harper & Row 1983), p.513–24 {{ISBN|0-06-042987-9}}</ref> One pair of nitrite linkage isomers have structures {{chem2|(NH3)5CoNO2(2+)}} (nitro isomer) and {{chem2|(NH3)5CoONO(2+)}} (nitrito isomer).<ref name=Jolly/>
# '''[[Coordination isomerism]]''' occurs when both positive and negative ions of a salt are complex ions and the two isomers differ in the distribution of ligands between the cation and the anion. For example, {{chem2|[Co(NH3)6][Cr(CN)6]}} and {{chem2|[Cr(NH3)6][Co(CN)6]}}.<ref name=Huheey/>

==Electronic properties==
Many of the properties of transition metal complexes are dictated by their electronic structures. The electronic structure can be described by a relatively ionic model that ascribes formal charges to the metals and ligands. This approach is the essence of [[crystal field theory]] (CFT).  Crystal field theory, introduced by [[Hans Bethe]] in 1929, gives a [[quantum mechanics|quantum mechanically]] based attempt at understanding complexes.  But crystal field theory treats all interactions in a complex as ionic and assumes that the ligands can be approximated by negative point charges.

More sophisticated models embrace covalency, and this approach is described by [[ligand field theory]] (LFT) and [[Molecular orbital theory]] (MO). Ligand field theory, introduced in 1935 and built from molecular orbital theory, can handle a broader range of complexes and can explain complexes in which the interactions are [[covalent]]. The chemical applications of [[group theory]] can aid in the understanding of crystal or ligand field theory, by allowing simple, symmetry based solutions to the formal equations.

Chemists tend to employ the simplest model required to predict the properties of interest; for this reason, CFT has been a favorite for the discussions when possible. MO and LF theories are more complicated, but provide a more realistic perspective.

The electronic configuration of the complexes gives them some important properties:

[[File:Copper complex.jpg|thumb|Synthesis of copper(II)-tetraphenylporphyrin, a metal complex, from [[tetraphenylporphyrin]] and [[copper(II) acetate monohydrate]].]]

===Color of transition metal complexes===
Transition metal complexes often have spectacular colors caused by electronic transitions by the absorption of light. For this reason they are often applied as [[Pigment#Physical basis|pigments]]. Most transitions that are related to colored metal complexes are either d–d transitions or [[charge transfer band]]s.  In a d–d transition, an electron in a d&nbsp;orbital on the metal is excited by a photon to another d orbital of higher energy, therefore d–d transitions occur only for partially-filled d-orbital complexes (d<sup>1–9</sup>). For complexes having d<sup>0</sup> or d<sup>10</sup> configuration, charge transfer is still possible even though d–d transitions are not. A charge transfer band entails promotion of an electron from a metal-based orbital into an empty ligand-based orbital ([[Charge transfer complex|metal-to-ligand charge transfer]] or MLCT).  The converse also occurs: excitation of an electron in a ligand-based orbital into an empty metal-based orbital ([[Charge transfer complex|ligand-to-metal charge transfer]] or LMCT). These phenomena can be observed with the aid of electronic spectroscopy; also known as [[UV-Vis]].<ref>{{cite book |last1= Harris |first1= D. |last2= Bertolucci |first2= M. |title= Symmetry and Spectroscopy |year= 1989 |publisher= Dover Publications | isbn= 9780486661445 }}</ref> For simple compounds with high symmetry, the d–d transitions can be assigned using [[Tanabe–Sugano diagram]]s.  These assignments are gaining increased support with [[computational chemistry]].

{| class="wikitable"
|+ Colours of Various Example Coordination Complexes
|-
! &nbsp;
! Fe<sup>2+</sup>
! Fe<sup>3+</sup>
! Co<sup>2+</sup>
! Cu<sup>2+</sup>
! Al<sup>3+</sup>
! Cr<sup>3+</sup>
|-
! [[Metal ions in aqueous solution|Hydrated Ion]]
| style="background: #CBE9AD;" | {{tooltip|2=Hexaaquairon(2+) cation|[Fe(H<sub>2</sub>O)<sub>6</sub>]<sup>2+</sup>|dotted=no}}     <br/>Pale green<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #EAD558;" | {{tooltip|2=Hexaaquairon(3+) cation|[Fe(H<sub>2</sub>O)<sub>6</sub>]<sup>3+</sup>|dotted=no}}    <br/>Yellow/brown<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #FF99CB;" | {{tooltip|2=Hexaaquacobalt(2+) cation|[Co(H<sub>2</sub>O)<sub>6</sub>]<sup>2+</sup>|dotted=no}}<br/>Pink<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #C7D9F1;" | {{tooltip|2=Hexaaquacopper(2+) cation|[Cu(H<sub>2</sub>O)<sub>6</sub>]<sup>2+</sup>|dotted=no}}<br/>Blue<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #F2F2F2;" | {{tooltip|2=Hexaaquaaluminium(3+) cation|[Al(H<sub>2</sub>O)<sub>6</sub>]<sup>3+</sup>|dotted=no}}<br/>Colourless<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #D7E3BD;" | {{tooltip|2=Hexaaquachromium(3+) cation|[Cr(H<sub>2</sub>O)<sub>6</sub>]<sup>3+</sup>|dotted=no}}<br/>Green<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
|-
! (OH)<sup>−</sup>, dilute
| style="background: #92D14F;" | {{tooltip|2=Tetraaquadihydroxidoiron|[Fe(H<sub>2</sub>O)<sub>4</sub>(OH)<sub>2</sub>]|dotted=no}} <br/>Dark green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #9B752A;" | {{tooltip|2=Triaquatrihydroxidoiron|[Fe(H<sub>2</sub>O)<sub>3</sub>(OH)<sub>3</sub>]|dotted=no}}<br/>Brown<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #8AE5D6;" | {{tooltip|2=Tetraaquadihydroxidocobalt|[Co(H<sub>2</sub>O)<sub>4</sub>(OH)<sub>2</sub>]|dotted=no}}<br/>Blue/green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #8EB2E2;" | {{tooltip|2=Tetraaquadihydroxidocopper|[Cu(H<sub>2</sub>O)<sub>4</sub>(OH)<sub>2</sub>]|dotted=no}}<br/>Blue<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #FFFFFF;" | {{tooltip|2=Triaquatrihydroxidoaluminium|[Al(H<sub>2</sub>O)<sub>3</sub>(OH)<sub>3</sub>]|dotted=no}}<br/>White<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #76923D;" | {{tooltip|2=Triaquatrihydroxidochromium|[Cr(H<sub>2</sub>O)<sub>3</sub>(OH)<sub>3</sub>]|dotted=no}}<br/>Green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
|-
! (OH)<sup>−</sup>, concentrated
| style="background: #92D14F;" | {{tooltip|2=Tetraaquadihydroxidoiron|[Fe(H<sub>2</sub>O)<sub>4</sub>(OH)<sub>2</sub>]|dotted=no}} <br/>Dark green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #9B752A;" | {{tooltip|2=Triaquatrihydroxidoiron|[Fe(H<sub>2</sub>O)<sub>3</sub>(OH)<sub>3</sub>]|dotted=no}}<br/>Brown<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #8AE5D6;" | {{tooltip|2=Tetraaquadihydroxidocobalt|[Co(H<sub>2</sub>O)<sub>4</sub>(OH)<sub>2</sub>]|dotted=no}}<br/>Blue/green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #8EB2E2;" | {{tooltip|2=Tetraaquadihydroxidocopper|[Cu(H<sub>2</sub>O)<sub>4</sub>(OH)<sub>2</sub>]|dotted=no}}<br/>Blue<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #FFFFFF;" | {{tooltip|2=Tetrahydroxidoaluminium|[Al(OH)<sub>4</sub>]<sup>−</sup>|dotted=no}}<br/>Colourless<br/>Solution
| style="background: #C3D59B;" | {{tooltip|2=Hexahydroxidochromate(3−) anion|[Cr(OH)<sub>6</sub>]<sup>3−</sup>|dotted=no}}<br/>Green<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
|-
! NH<sub>3</sub>, dilute
| style="background: #92D14F;" | {{tooltip|2=Hexaammineiron|[Fe(NH<sub>3</sub>)<sub>6</sub>]<sup>2+</sup>|dotted=no}}<br/>Dark green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #9B752A;" | {{tooltip|2=Hexaammineiron|[Fe(NH<sub>3</sub>)<sub>6</sub>]<sup>3+</sup>|dotted=no}}<br/>Brown<br/> {{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #D3D359;" | {{tooltip|2=Hexaamminecobalt(2+) cation|[Co(NH<sub>3</sub>)<sub>6</sub>]<sup>2+</sup>|dotted=no}}<br/>Straw coloured<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #548DD4;" | {{tooltip|2=Tetraamminediaquacopper(2+) cation|[Cu(NH<sub>3</sub>)<sub>4</sub>(H<sub>2</sub>O)<sub>2</sub>]<sup>2+</sup>|dotted=no}}<br/>Deep blue<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #FFFFFF;" | {{tooltip|2=Triamminealuminium|[Al(NH<sub>3</sub>)<sub>3</sub>]<sup>3+</sup>|dotted=no}}<br/>White<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #CC0099;" | {{tooltip|2=hexaamminechromium(3+) cation|[Cr(NH<sub>3</sub>)<sub>6</sub>]<sup>3+</sup>|dotted=no}}<br/>Purple<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
|-
! NH<sub>3</sub>, concentrated
| style="background: #92D14F;" | {{tooltip|2=Hexaammineiron|[Fe(NH<sub>3</sub>)<sub>6</sub>]<sup>2+</sup>|dotted=no}}<br/>Dark green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #9B752A;" | {{tooltip|2=Hexaammineiron|[Fe(NH<sub>3</sub>)<sub>6</sub>]<sup>3+</sup>|dotted=no}}<br/>Brown<br/> {{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #D3D359;" | {{tooltip|2=Hexaamminecobalt(2+) cation|[Co(NH<sub>3</sub>)<sub>6</sub>]<sup>2+</sup>|dotted=no}}<br/>Straw coloured<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #548DD4;" | {{tooltip|2=Tetraamminediaquacopper(2+) cation|[Cu(NH<sub>3</sub>)<sub>4</sub>(H<sub>2</sub>O)<sub>2</sub>]<sup>2+</sup>|dotted=no}}<br/>Deep blue<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
| style="background: #FFFFFF;" | {{tooltip|2=Triamminealuminium|[Al(NH<sub>3</sub>)<sub>3</sub>]<sup>3+</sup>|dotted=no}}<br/>White<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #CC0099;" | {{tooltip|2=hexaamminechromium(3+) cation|[Cr(NH<sub>3</sub>)<sub>6</sub>]<sup>3+</sup>|dotted=no}}<br/>Purple<br/>{{tooltip|2=Suspended in solution|Solution|dotted=no}}
|-
! (CO<sub>3</sub>)<sup>2-</sup>
| style="background: #92D14F;" | {{tooltip|2=Iron(II) carbonate|FeCO<sub>3</sub>|dotted=no}}<br/>Dark green<br                            />{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
| style="background: #9B752A;" | {{tooltip|2=Iron(III) carbonate|Fe<sub>2</sub>(CO<sub>3</sub>)<sub>3</sub>|dotted=no}}<br/>Brown<br                            />{{tooltip|2=Precipitates from solution|Precipitate+bubbles|dotted=no}}
| style="background: #FF99CB;"| {{tooltip|2=Cobalt(II) carbonate|CoCO<sub>3</sub>|dotted=no}}<br/>Pink<br/>{{tooltip|2=Precipitates from solution with an effervescence of Carbon Dioxide|Precipitate|dotted=no}}
| style="background: #8AE5D6;" | {{tooltip|2=Copper(II) carbonate|CuCO<sub>3</sub>|dotted=no}}<br/>Blue/green<br/>{{tooltip|2=Precipitates from solution|Precipitate|dotted=no}}
|}

===Colors of lanthanide complexes===
Superficially [[lanthanide]] complexes are similar to those of the transition metals in that some are colored. However, for the common Ln<sup>3+</sup> ions (Ln = lanthanide) the colors are all pale, and hardly influenced by the nature of the ligand. The colors are due to 4f electron transitions. As the 4f orbitals in lanthanides are "buried" in the xenon core and shielded from the ligand by the 5s and 5p orbitals they are therefore not influenced by the ligands to any great extent leading to a much smaller [[Crystal field theory|crystal field]] splitting than in the transition metals. The absorption spectra of an Ln<sup>3+</sup> ion approximates to that of the free ion where the electronic states are described by [[Angular momentum coupling#Spin-orbit coupling|spin-orbit coupling]]. This contrasts to the transition metals where the ground state is split by the crystal field. Absorptions for Ln<sup>3+</sup> are weak as electric dipole transitions are parity forbidden ([[Laporte rule|Laporte forbidden]]) but can gain intensity due to the effect of a low-symmetry ligand field or mixing with higher electronic states (''e.g.'' d orbitals). f-f absorption bands are extremely sharp which contrasts with those observed for transition metals which generally have broad bands.<ref name = "C&W6th">{{Cotton&Wilkinson6th}}</ref><ref name=CottonSA2006>{{cite book |last=Cotton |first=Simon |year=2006 |title=Lanthanide and Actinide Chemistry|publisher= John Wiley & Sons Ltd}}</ref> This can lead to extremely unusual effects, such as significant color changes under different forms of lighting.

===Magnetism===
{{main|magnetochemistry}}
Metal complexes that have unpaired electrons are [[paramagnetic]]. This can be due to an odd number of electrons overall, or to incomplete electron-pairing.  Thus, monomeric Ti(III) species have one "d-electron" and must be [[paramagnetism|(para)magnetic]], regardless of the geometry or the nature of the ligands.  Ti(II), with two d-electrons, forms some complexes that have two unpaired electrons and others with none. This effect is illustrated by the compounds TiX<sub>2</sub>[(CH<sub>3</sub>)<sub>2</sub>PCH<sub>2</sub>CH<sub>2</sub>P(CH<sub>3</sub>)<sub>2</sub>]<sub>2</sub>: when X&nbsp;=&nbsp;[[Chlorine|Cl]], the complex is paramagnetic ([[high spin|high-spin]] configuration), whereas when X&nbsp;=&nbsp;[[methyl group|CH<sub>3</sub>]], it is diamagnetic ([[low spin|low-spin]] configuration). Ligands provide an important means of adjusting the [[ground state]] properties.

In bi- and polymetallic complexes, in which the individual centres have an odd number of electrons or that are high-spin, the situation is more complicated.  If there is interaction (either direct or through ligand) between the two (or more) metal centres, the electrons may couple ([[Antiferromagnetism|antiferromagnetic coupling]], resulting in a diamagnetic compound), or they may enhance each other ([[Ferromagnetism|ferromagnetic coupling]]).  When there is no interaction, the two (or more) individual metal centers behave as if in two separate molecules.

===Reactivity===
Complexes show a variety of possible reactivities:<ref>R. G. Wilkins Kinetics and Mechanism of Reactions of Transition Metal Complexes, 2nd Edition, VCH, Weinheim, 1991. {{ISBN|1-56081-125-0}}</ref>

* Electron transfers
*: [[Electron transfer]] (ET) between metal ions can occur via two distinct mechanisms, [[Inner sphere electron transfer|inner]] and [[outer sphere electron transfer]]s. In an inner sphere reaction, a [[bridging ligand]] serves as a conduit for ET.
* (Degenerate) [[ligand exchange]]
*: One important indicator of reactivity is the rate of degenerate exchange of ligands.  For example, the rate of interchange of coordinate water in [M(H<sub>2</sub>O)<sub>6</sub>]<sup>''n''+</sup> complexes varies over 20 orders of magnitude.  Complexes where the ligands are released and rebound rapidly are classified as labile.  Such labile complexes can be quite stable thermodynamically.  Typical labile metal complexes either have low-charge (Na<sup>+</sup>), electrons in d-orbitals that are [[antibonding]] with respect to the ligands (Zn<sup>2+</sup>), or lack covalency (Ln<sup>3+</sup>, where Ln is any lanthanide).  The lability of a metal complex also depends on the high-spin vs. low-spin configurations when such is possible.  Thus, high-spin Fe(II) and Co(III) form labile complexes, whereas low-spin analogues are inert.  Cr(III) can exist only in the low-spin state (quartet), which is inert because of its high formal oxidation state, absence of electrons in orbitals that are M–L antibonding, plus some "ligand field stabilization" associated with the d<sup>3</sup> configuration.
* Associative processes
*: Complexes that have unfilled or half-filled orbitals are often capable of reacting with substrates.  Most substrates have a singlet ground-state; that is, they have lone electron pairs (e.g., water, amines, ethers), so these substrates need an empty orbital to be able to react with a metal centre.  Some substrates (e.g., molecular oxygen) [[triplet oxygen|have a triplet ground state]], which results that metals with half-filled orbitals have a tendency to react with such substrates (it must be said that the [[dioxygen]] molecule also has lone pairs, so it is also capable to react as a 'normal' Lewis base).

If the ligands around the metal are carefully chosen, the metal can aid in ([[stoichiometric]] or [[catalytic]]) transformations of molecules or be used as a sensor.

==Classification==
Metal complexes, also known as coordination compounds, include virtually all metal compounds.<ref>Exception: metal vapors, [[plasma (physics)|plasma]]s, and [[alloy]]s.</ref>  The study of "coordination chemistry" is the study of "inorganic chemistry" of all [[alkali metal|alkali]] and [[alkaline earth metal]]s, [[transition metal]]s, [[lanthanide]]s, [[actinides]], and [[metalloid]]s. Thus, coordination chemistry is the chemistry of the majority of the periodic table.  Metals and metal ions exist, in the condensed phases at least, only surrounded by ligands.

The areas of coordination chemistry can be classified according to the nature of the ligands, in broad terms:
* Classical (or "[[Alfred Werner|Werner]] Complexes"): Ligands in classical coordination chemistry bind to metals, almost exclusively, via their [[lone pair]]s of electrons residing on the main-group atoms of the ligand. Typical ligands are H<sub>2</sub>O, NH<sub>3</sub>, [[chloride|Cl<sup>−</sup>]], [[Cyanide|CN<sup>−</sup>]], [[ethylenediamine|en]].  Some of the simplest members of such complexes are described in [[metal aquo complex]]es, [[metal ammine complex]]es,
: Examples: [Co([[EDTA]])]<sup>−</sup>, [[Cobalt(III) hexammine chloride|[Co(NH<sub>3</sub>)<sub>6</sub>]<sup>3+</sup>]], [[Potassium ferrioxalate|[Fe(C<sub>2</sub>O<sub>4</sub>)<sub>3</sub>]<sup>3-</sup>]]
* [[Organometallic chemistry]]:  Ligands are organic (alkenes, alkynes, alkyls) as well as "organic-like" ligands such as phosphines, hydride, and CO.
: Example: [[Cyclopentadienyliron dicarbonyl dimer|(C<sub>5</sub>H<sub>5</sub>)Fe(CO)<sub>2</sub>CH<sub>3</sub>]]
* [[Bioinorganic chemistry]]: Ligands are those provided by nature, especially including the side chains of amino acids, and many [[cofactor (biochemistry)|cofactor]]s such as [[porphyrin]]s.
: Example: [[hemoglobin]] contains [[heme]], a porphyrin complex of iron
: Example: [[chlorophyll]] contains a porphyrin complex of magnesium
: Many natural ligands are "classical"  especially including water.
* [[Atom cluster|Cluster chemistry]]: Ligands include all of the above as well as other metal ions or atoms as well.
: Example Ru<sub>3</sub>(CO)<sub>12</sub>
* In some cases there are combinations of different fields:
:Example: [[Iron–sulfur protein|[Fe<sub>4</sub>S<sub>4</sub>(Scysteinyl)<sub>4</sub>]<sup>2−</sup>]], in which a cluster is embedded in a biologically active species.

[[Mineralogy]], [[materials science]], and [[solid state chemistry]]&nbsp;– as they apply to metal ions&nbsp;– are subsets of coordination chemistry in the sense that the metals are surrounded by ligands.  In many cases these ligands are oxides or sulfides, but the metals are coordinated nonetheless, and the principles and guidelines discussed below apply. In [[water of crystallization|hydrate]]s, at least some of the ligands are water molecules. It is true that the focus of mineralogy, materials science, and solid state chemistry differs from the usual focus of coordination or inorganic chemistry. The former are concerned primarily with polymeric structures, properties arising from a collective effects of many highly interconnected metals. In contrast, coordination chemistry focuses on reactivity and properties of complexes containing individual metal atoms or small ensembles of metal atoms.

==Nomenclature of coordination complexes==
The basic procedure for naming a complex is:
# When naming a complex ion, the ligands are named before the metal ion.
# The ligands' names are given in alphabetical order. Numerical prefixes do not affect the order.
#* Multiple occurring monodentate ligands receive a prefix according to the number of occurrences: ''di-'', ''tri-'', ''tetra-'', ''penta-'', or ''hexa-''.
#* Multiple occurring polydentate ligands (e.g., ethylenediamine, oxalate) receive ''bis-'', ''tris-'', ''tetrakis-'', etc.
#* Anions end in ''o''.  This replaces the final 'e' when the anion ends with '-ide', '-ate' or '-ite', e.g. ''chloride'' becomes ''chlorido'' and ''sulfate'' becomes ''sulfato''. Formerly, '-ide' was changed to '-o' (e.g. ''chloro'' and ''cyano''), but this rule has been modified in the 2005 IUPAC recommendations and the correct forms for these ligands are now ''chlorido'' and ''cyanido''.<ref name="iupac_org">{{cite web |url= http://www.iupac.org/fileadmin/user_upload/databases/Red_Book_2005.pdf |title= Nomenclature of Inorganic Chemistry IUPAC Recommendations 2005 |at= section 1.6.4 (p. 10–11) |publisher= [[IUPAC]] |access-date= 2016-03-06 |archive-url= https://web.archive.org/web/20141222172055/http://www.iupac.org/fileadmin/user_upload/databases/Red_Book_2005.pdf |archive-date= 2014-12-22 |url-status= dead }}</ref>
#* Neutral ligands are given their usual name, with some exceptions: NH<sub>3</sub> becomes ''[[ammine]]''; H<sub>2</sub>O becomes ''aqua'' or ''aquo''; CO becomes ''carbonyl''; NO becomes ''nitrosyl''.
# Write the name of the central atom/ion.  If the complex is an anion, the central atom's name will end in ''-ate'', and its Latin name will be used if available (except for mercury).
# The oxidation state of the central atom is to be specified (when it is one of several possible, or zero), and should be written as a Roman numeral (or 0) enclosed in parentheses.
# Name of the cation should be preceded by the name of anion. (if applicable, as in last example)

Examples:
{|class="wikitable"
!metal
!changed to
|-
|cobalt
|cobaltate
|-
|aluminium
|aluminate
|-
|chromium
|chromate
|-
|vanadium
|vanadate
|-
|copper
|cuprate
|-
|iron
|ferrate
|}

: [Cd(CN)<sub>2</sub>(en)<sub>2</sub>] → dicyanidobis(ethylenediamine)cadmium(II)
: [CoCl(NH<sub>3</sub>)<sub>5</sub>]SO<sub>4</sub> → pentaamminechloridocobalt(III) sulfate
: [Cu(H<sub>2</sub>O)<sub>6</sub>] <sup>2+</sup>  → hexaaquacopper(II) ion
: [CuCl<sub>5</sub>NH<sub>3</sub>]<sup>3−</sup> → amminepentachloridocuprate(II) ion
: K<sub>4</sub>[Fe(CN)<sub>6</sub>] → potassium hexacyanidoferrate(II)
: [NiCl<sub>4</sub>]<sup>2−</sup> → tetrachloridonickelate(II) ion (The use of chloro- was removed from IUPAC naming convention)<ref name="iupac_org" />

The coordination number of ligands attached to more than one metal (bridging ligands) is indicated by a subscript to the Greek symbol [[mu (letter)|μ]] placed before the ligand name. Thus the [[Dimer (chemistry)|dimer]] of [[aluminium trichloride]] is described by Al<sub>2</sub>Cl<sub>4</sub>(μ<sub>2</sub>-Cl)<sub>2</sub>.

Any anionic group can be electronically stabilized by any cation. An anionic complex can be stabilised by a hydrogen cation, becoming an acidic complex which can dissociate to release the cationic hydrogen. This kind of complex compound has a name with "ic" added after the central metal. For example, H<sub>2</sub>[Pt(CN)<sub>4</sub>] has the name tetracyanoplatinic (II) acid.

==Stability constant==
{{Main|Stability constants of complexes}}

The affinity of metal ions for ligands is described by a stability constant, also called the formation constant, and is represented by the symbol K<sub>f</sub>. It is the [[equilibrium constant]] for its assembly from the constituent metal and ligands, and can be calculated accordingly, as in the following example for a simple case:

:xM <sub>(aq)</sub> + yL <sub>(aq) </sub> {{eqm}} zZ <sub>(aq)</sub>

:<math>K_f = \frac{[\text{Z}]^z}{[\text{M}]^x[\text{L}]^y}</math>

where : x, y, and z are the [[stoichiometric]] coefficients of each species. M stands for metal / metal ion , the L for Lewis bases , and finally Z for complex ions. Formation constants vary widely.  Large values indicate that the metal has high affinity for the ligand, provided the system is at equilibrium.<ref>{{Cite web|url = http://www2.ucdsb.on.ca/tiss/stretton/CHEM2/solubil8.htm|title = Complex Ion Equilibria|access-date = 2015-04-22|archive-date = 2015-03-08|archive-url = https://web.archive.org/web/20150308110908/http://www2.ucdsb.on.ca/tiss/stretton/CHEM2/solubil8.htm|url-status = dead}}</ref>

Sometimes the stability constant will be in a different form known as the constant of destability. This constant is expressed as the inverse of the constant of formation and is denoted as K<sub>d</sub> = 1/K<sub>f</sub> .<ref>{{Cite web|url = http://www2.bakersfieldcollege.edu/wcooper/Chem%20B1B%20Notes%20Fall_09/Chap_17_Solubility_Equilibrium_Notes.pdf|title = Solubility and Complex-ion Equilibria|last = Stretton|first = Tom|access-date = 2015-04-22|archive-date = 2018-09-20|archive-url = https://web.archive.org/web/20180920175811/http://www2.bakersfieldcollege.edu/wcooper/Chem%20B1B%20Notes%20Fall_09/Chap_17_Solubility_Equilibrium_Notes.pdf|url-status = dead}}</ref> This constant represents the reverse reaction for the decomposition of a complex ion into its individual metal and ligand components. When comparing the values for K<sub>d</sub>, the larger the value, the more unstable the complex ion is.

As a result of these complex ions forming in solutions they also can play a key role in solubility of other compounds. When a complex ion is formed it can alter the concentrations of its components in the solution. For example:

:Ag{{su|p=+|b=(aq)}} + 2{{nbsp}}NH<sub>3</sub> {{eqm}} Ag(NH<sub>3</sub>){{su|b=2|p=+}}

:AgCl<sub>(s)</sub> + H<sub>2</sub>O<sub>(l)</sub> {{eqm}} Ag{{su|b=(aq)|p=+}} + Cl{{su|b=(aq)|p=−}}

If these reactions both occurred in the same reaction vessel, the solubility of the silver chloride would be increased by the presence of NH<sub>4</sub>OH because formation of the Diammine argentum(I) complex consumes a significant portion of the free silver ions from the solution. By [[Le Chatelier's principle]], this causes the equilibrium reaction for the dissolving of the silver chloride, which has silver ion as a product, to shift to the right.

This new solubility can be calculated given the values of K<sub>f</sub> and K<sub>sp</sub> for the original reactions. The solubility is found essentially by combining the two separate equilibria into one combined equilibrium reaction and this combined reaction is the one that determines the new solubility. So K<sub>c</sub>, the new solubility constant, is denoted by:
:<math>K_c = K_{sp} K_f</math>
<!--==Specific metal complexes==

===Mercury===

The speciation, solubility, mobility, and toxicity of [[Mercury (element)|mercury]] within aquatic environments are strongly influenced by its [[Chemical Reaction|complexation]] with inorganic and organic [[ligands]]; most notable is mercury’s interaction with [[dissolved organic matter]] (DOM).  As a result, the speciation of mercury depends on the concentration of each ligand and the stability constants of mercury complexes they form.  For mercury, important inorganic ligands include hydroxide, chloride, and sulfide.  However, complexation by natural organic compounds often controls the [[aqueous geochemistry|biogeochemical]] cycling of mercury. For example, complexation with DOM may limit the availability of Hg<sup>2+</sup> for conversion to methylmercury or enhance the formation of elemental mercury (Hg<sup>0</sup>) from Hg<sup>2+</sup>, further lowering the availability of Hg<sup>2+</sup> for conversion to methylmercury.<ref name="Lamborg et al">Lamborg, C. H., C. Tseng, W. F. Fitzgerald, P. H. Balcom, and C. R. Hammerschmidt, 2003, Determination of the Mercury Complexation Characteristics of Dissolved Organic Matter in Natural Waters with “Reducible Hg” Titrations: Environmental Science and Technology, 37, 3316-3322.</ref><ref name ="Ravichandran et al">Ravichandran, M., 2004, Interactions between mercury and dissolved organic matter—a review: Chemosphere, 55, 319-331.</ref>

Mercury binding to dissolved organic matter is evaluated in terms of the [[stability constants of complexes|stability constants]] of Hg-DOM complexes.<ref name="Ravichandran et al" />  The complexation reaction between Hg<sup>2+</sup> and an organic ligand is assumed to take the following form:

Hg<sup>2+</sup> + L<sup>n−</sup> → 2 HgL<sup>(2-n)+</sup>

where K, the stability constant, is equal to:

K= [HgL<sup>(2-n)</sup>]/[Hg<sup>2+</sup>][L<sup>n−</sup>].

<ref name="Lamborg et al" /> Metal cations bind to the acid sites in organic matter, the most common of which include carboxylic acids, phenols, amines, alcohols, and thiols.  Mercury is classified as a type B metal and shows a preference for ligands of sulfur, the less electronegative halides, and nitrogen, over ligands containing oxygen.  Therefore, mercury is expected to preferentially bind with thiol and other sulfur-containing functional groups which, despite their relatively low abundance in DOM, far exceed the amount of mercury available in aquatic environments.<ref name="Ravichandran et al" /> Previous research has shown that binding of Hg<sup>2+</sup> by organic ligands does not occur immediately when both are present; instead, complexation tends to follow a pseudo-first-order rate constant with exponential decay.<ref name="Lamborg et al" /> 
 
Predicting mercury speciation due to Hg-DOM complexes is difficult due to organic matter heterogeneity, electrostatic effects, and the variation in stability constants; however, recent studies have shown conditional stability constants for mercury binding to be in the range of 10<sup>22</sup> – 10<sup>28</sup>.<ref name="Ravichandran et al" /> 
    
Competitive ligand exchange (CLE) experiments, in which Hg binding to natural organic ligands is measured in the presence of an added ligand whose complexation with Hg<sup>2+</sup> is well characterized, is used to determine the concentrations and apparent stability constants of natural mercury complexes.  One such experiment used both chloride and thiosalicyclic acid (TSA) as competing ligands; estimated conditional stability constants ranged from 10<sup>26.1</sup> to 10<sup>26.9</sup> for chloride competition and 10<sup>27.3</sup> to 10<sup>29.2</sup> for TSA competition.<ref name="Han et al">Han, S. and G. A. Gill, 2005, Determination of Mercury Complexation in Coastal and Estuarine Waters Using Competitive Ligand Exchange Method: Environmental Science and Technology, 39, 6607-6615.</ref>  This study showed that lower concentrations of binding sites with higher stability constants are more important for Hg speciation than higher concentrations of weaker binding sites.

Conditional stability constants vary with pH due to competition with protons for binding sites.<ref name="Han et al" />  They also vary with salinity and, contrary to what may be expected, are generally lower in freshwater than seawater.<ref name="Lamborg et al" /> In seawater, organic complexes must have very high K values in order to compete with chloride for mercury complexation.  In freshwater systems, hydroxide is the most common inorganic ligand, yet its concentration is low enough that organic ligands do not need to have a high K value to compete for mercury complexation.  In both environments, organic compounds dominate mercury complexation.<ref name="Lamborg et al" /><ref name="Han et al" />

In examining the role of DOM in mercury speciation under sulfidic environments, we see that inorganic sulfide also plays an important role within anoxic environments due to the very strong binding of sulfide with mercury.  HgS{{su|p=0|b=(aq)}}, Hg(S<sub>2</sub>H)<sup>−</sup>, Hg(SH){{su|b=2|p=0}}, and [[mercury sulfide|HgS<sub>(s)</sub>]] are likely to be the most important species.  Recent studies however, have shown that stability constants of Hg-DOM complexation are higher than those for mercury sulfide complexation.  These results then imply that organic matter can out complete sulfide for the complexation of mercury within anoxic environments.<ref name="Ravichandran et al" />

DOM has been shown to affect the bioaccumulation of mercury via photochemical reduction and methylation.  Reduction of Hg<sup>2+</sup> to Hg<sup>0</sup> by sunlight is a commonly occurring process, yet is enhanced in the presence of DOM.  Conversely, photolysis of dissolved organic carbon (DOC) can produce radical oxygen species including hydroxyl radicals (<sup>−</sup>OH), which in turn have been shown to oxidize Hg<sup>0</sup> to Hg<sup>2+</sup>.<ref name="Ravichandran et al" />   Conversion of ionic mercury (especially Hg<sup>2+</sup>) to methyl mercury is an important process, as methyl mercury is a neurotoxin and has been show to bioaccumulate within the food chain.  Mercury methylation is a microbially mediated process wherein bacteria assimilate neutrally charged mercury species through passive diffusion.  Complexation with DOC limits this uptake mechanism as the DOC molecules are too large to pass through cell membranes; however, at low pH, DOC is less negatively charged and therefore less likely to complex mercury, thereby making mercury more available for methylation.  Additionally, DOM-mediated reduction of Hg<sup>2+</sup> to Hg<sup>0</sup> would further limit the availability of mercury for methylation by leading to the mercury volatilization.    Direct methylation of mercury can also occur by reaction with humic and fulvic acids in DOM.<ref name="Ravichandran et al" />-->

==Application of coordination compounds==
As metals only exist in solution as coordination complexes, it follows then that this class of compounds is useful in a wide variety of ways.

===Bioinorganic chemistry===
In [[bioinorganic chemistry]] and [[bioorganometallic chemistry]], coordination complexes serve either structural or catalytic functions. An estimated 30% of proteins contain metal ions.  Examples include the intensely colored [[Vitamin B12|vitamin B<sub>12</sub>]], the [[Heme|heme group]] in [[hemoglobin]], the [[cytochrome]]s, the [[Chlorin|chlorin group]] in [[chlorophyll]], and [[carboxypeptidase]], a hydrolytic enzyme important in digestion. Another complex ion enzyme is [[catalase]], which decomposes the cell's waste [[hydrogen peroxide]]. Synthetic coordination compounds are also used to bind to proteins and especially nucleic acids (e.g. anticancer drug [[cisplatin]]).

===Industry===
[[Homogeneous catalysis]] is a major application of coordination compounds for the production of organic substances.  Processes include [[hydrogenation]], [[hydroformylation]], [[oxidation]].  In one example, a combination of titanium trichloride and triethylaluminium gives rise to [[Ziegler–Natta catalyst]]s, used for the [[polymerization]] of ethylene and propylene to give polymers of great commercial importance as fibers, films, and plastics.

Nickel, cobalt, and copper can be extracted using [[hydrometallurgy|hydrometallurgical processes]] involving complex ions. They are extracted from their ores as [[Metal ammine complex|ammine]] complexes. Metals can also be separated using the selective precipitation and solubility of complex ions. Cyanide is used chiefly for extraction of gold and silver from their ores.

[[Phthalocyanine]] complexes are an important class of pigments.

===Analysis===
At one time, coordination compounds were used to identify the presence of metals in a sample. [[Qualitative inorganic analysis]] has largely been superseded by instrumental methods of analysis such as [[atomic absorption spectroscopy]] (AAS), [[inductively coupled plasma atomic emission spectroscopy]] (ICP-AES) and [[inductively coupled plasma mass spectrometry]] (ICP-MS).

==See also==
{{commons category|Coordination compounds}}
*[[Activated complex]]
*[[IUPAC nomenclature of inorganic chemistry]]
*[[Coordination cage]]
*[[Coordination geometry]]
*[[Coordination isomerism]]
*[[Coordination polymers]], in which coordination complexes are the repeating units.
*[[Inclusion compound]]s
*[[Organometallic chemistry]] deals with a special class of coordination compounds where organic fragments are bonded to a metal at least through one C&nbsp;atom.

==References==
{{reflist}}

==Further reading==
* De Vito, D.; Weber, J. ; Merbach, A. E. “Calculated Volume and Energy Profiles for Water Exchange on t<sub>2g</sub> <sup>6</sup> Rhodium(III) and Iridium(III) Hexaaquaions: Conclusive Evidence for an I<sub>a</sub> Mechanism” Inorganic Chemistry, 2004, Volume 43, pages 858–863. {{doi|10.1021/ic035096n}}
* Zumdahl, Steven S.  Chemical Principles, Fifth Edition. New York: Houghton Mifflin, 2005. 943–946, 957. {{OCLC|77760970}}
* Harris, D., Bertolucci, M., ''Symmetry and Spectroscopy''. 1989 New York, Dover Publications

==External links==
{{Wikibooks|A-level Chemistry/OCR (Salters)|Complexes}}
*[http://www.chemistry.wustl.edu/~edudev/LabTutorials/naming_coord_comp.html Naming Coordination Compounds]
*[http://www.wou.edu/las/physci/ch462/tmcolors.htm Transition Metal Complex Colors]

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[[Category:Coordination complexes| ]]
[[Category:Inorganic chemistry]]
[[Category:Transition metals]]
[[Category:Coordination chemistry]]