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Coordination geometry

December 03, 2023

Main article: Molecular geometry

The coordination geometry of an atom is the geometrical pattern defined by the atoms around the central atom. The term is commonly applied in the field of inorganic chemistry, where diverse structures are observed. The coodination geometry depends on the number, not the type, of ligands bonded to the metal centre as well as their locations. The number of atoms bonded is the coordination number. The geometrical pattern can be described as a polyhedron where the vertices of the polyhedron are the centres of the coordinating atoms in the ligands.[1]

The coordination preference of a metal often varies with its oxidation state. The number of coordination bonds (coordination number) can vary from two in K[Ag(CN)2] as high as 20 in Th(η5-C5H5)4.[2]

One of the most common coordination geometries is octahedral, where six ligands are coordinated to the metal in a symmetrical distribution, leading to the formation of an octahedron if lines were drawn between the ligands. Other common coordination geometries are tetrahedral and square planar.

Crystal field theory may be used to explain the relative stabilities of transition metal compounds of different coordination geometry, as well as the presence or absence of paramagnetism, whereas VSEPR may be used for complexes of main group element to predict geometry.

Crystallography usage edit

In a crystal structure the coordination geometry of an atom is the geometrical pattern of coordinating atoms where the definition of coordinating atoms depends on the bonding model used.[1] For example, in the rock salt ionic structure each sodium atom has six near neighbour chloride ions in an octahedral geometry and each chloride has similarly six near neighbour sodium ions in an octahedral geometry. In metals with the body centred cubic (bcc) structure each atom has eight nearest neighbours in a cubic geometry. In metals with the face centred cubic (fcc) structure each atom has twelve nearest neighbours in a cuboctahedral geometry.

Table of coordination geometries edit

A table of the coordination geometries encountered is shown below with examples of their occurrence in complexes found as discrete units in compounds and coordination spheres around atoms in crystals (where there is no discrete complex).

Coordination number Geometry Examples of discrete (finite) complex Examples in crystals (infinite solids)
2 linear   [Ag(CN)2] in K[Ag(CN)2] [3] Ag in silver cyanide,
Au in AuI [2]
3 trigonal planar   [HgI3][2] O in TiO2 rutile structure[3]
4 tetrahedral   [CoCl4]2−[2] Zn and S in zinc sulfide, Si in silicon dioxide[3]
4 square planar   [AgF4][2] CuO[3]
5 trigonal bipyramidal   [SnCl5][3]
5 square pyramidal   [InCl5]2− in [N(CH2CH3)4]2[InCl5][2]
6 octahedral   [Fe(H2O)6]2+[2] Na and Cl in NaCl[3]
6 trigonal prismatic   W(CH3)6[4] As in NiAs, Mo in MoS2[3]
7 pentagonal bipyramidal   [ZrF7]3− in [NH4]3[ZrF7][3] Pa in PaCl5
7 capped octahedral   [MoF7][5] La in A-La2O3
7 capped trigonal prismatic   [TaF7]2− in K2[TaF7][3]
8 square antiprismatic   [TaF8]3− in Na3[TaF8][3]
[Zr(H2O)8]4+ aqua complex[6]		 Thorium(IV) iodide[3]
8 dodecahedral
(note: whilst this is the term generally
used, the correct term is "bisdisphenoid"[3]
or "snub disphenoid" as this polyhedron is a deltahedron) 		  [Mo(CN)8]4− in K4[Mo(CN)8]·2H2O[3] Zr in K2[ZrF6][3]
8 bicapped trigonal prismatic   [ZrF8]4−[7] PuBr3[3]
8 cubic Caesium chloride, calcium fluoride
8 hexagonal bipyramidal   N in Li3N[3]
8 octahedral, trans-bicapped Ni in nickel arsenide, NiAs; 6 As neighbours + 2 Ni capping[8]
8 trigonal prismatic, triangular face bicapped Ca in CaFe2O4[3]
9 tricapped trigonal prismatic   [ReH9]2− in potassium nonahydridorhenate[2]
[Th(H2O)9]4+ aqua complex[6]		 SrCl2·6H2O, Th in Rb[Th3F13][3]
9 capped square antiprismatic   [Th(tropolonate)4(H2O)][2][clarification needed] La in LaTe2[3]
10 bicapped square antiprismatic [Th(C2O4)4]2−[2]
11 Th in [ThIV(NO3)4(H2O)3] (NO3 is bidentate)[2]
12 icosahedron   Th in [Th(NO3)6]2− ion in Mg[Th(NO3)6]·8H2O[3]
12 cuboctahedron   ZrIV(η3-[BH4]4) atoms in fcc metals e.g. Ca[3]
12 anticuboctahedron (triangular orthobicupola)   atoms in hcp metals e.g. Sc[3]
12 bicapped hexagonal antiprismatic U[BH4]4[2]

Naming of inorganic compounds edit

IUPAC have introduced the polyhedral symbol as part of their IUPAC nomenclature of inorganic chemistry 2005 recommendations to describe the geometry around an atom in a compound.[9]
IUCr have proposed a symbol which is shown as a superscript in square brackets in the chemical formula. For example, CaF2 would be Ca[8cb]F2[4t], where [8cb] means cubic coordination and [4t] means tetrahedral. The equivalent symbols in IUPAC are CU−8 and T−4 respectively.[1]
The IUPAC symbol is applicable to complexes and molecules whereas the IUCr proposal applies to crystalline solids.

See also edit

References edit

  1. ^ a b c J. Lima-de-Faria; E. Hellner; F. Liebau; E. Makovicky; E. Parthé (1990). "Report of the International Union of Crystallography Commission on Crystallographic Nomenclature Subcommittee on the Nomenclature of Inorganic Structure Types". Acta Crystallogr. A. 46: 1–11. doi:10.1107/S0108767389008834.
  2. ^ a b c d e f g h i j k l Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. ISBN 978-0-08-037941-8.
  3. ^ a b c d e f g h i j k l m n o p q r s t u v Wells A.F. (1984) Structural Inorganic Chemistry 5th edition Oxford Science Publications ISBN 0-19-855370-6
  4. ^ Housecroft, C. E.; Sharpe, A. G. (2004). Inorganic Chemistry (2nd ed.). Prentice Hall. p. 725. ISBN 978-0-13-039913-7.
  5. ^ Kaupp, Martin (2001). ""Non-VSEPR" Structures and Bonding in d(0) Systems". Angew Chem Int Ed Engl. 40 (1): 3534–3565. doi:10.1002/1521-3773(20011001)40:19<3534::AID-ANIE3534>3.0.CO;2-#. PMID 11592184.
  6. ^ a b Persson, Ingmar (2010). "Hydrated metal ions in aqueous solution: How regular are their structures?". Pure and Applied Chemistry. 82 (10): 1901–1917. doi:10.1351/PAC-CON-09-10-22. ISSN 0033-4545.
  7. ^ Jeremy K. Burdett; Roald Hoffmann; Robert C. Fay (1978). "Eight-Coordination". Inorganic Chemistry. 17 (9): 2553–2568. doi:10.1021/ic50187a041.
  8. ^ David G. Pettifor, Bonding and Structure of Molecules and Solids, 1995, Oxford University Press,ISBN 0-19-851786-6
  9. ^ NOMENCLATURE OF INORGANIC CHEMISTRY IUPAC Recommendations 2005 ed. N. G. Connelly et al. RSC Publishing http://www.chem.qmul.ac.uk/iupac/bioinorg/

December 03, 2023
coordination, geometry, main, article, molecular, geometry, coordination, geometry, atom, geometrical, pattern, defined, atoms, around, central, atom, term, commonly, applied, field, inorganic, chemistry, where, diverse, structures, observed, coodination, geom. Main article Molecular geometry The coordination geometry of an atom is the geometrical pattern defined by the atoms around the central atom The term is commonly applied in the field of inorganic chemistry where diverse structures are observed The coodination geometry depends on the number not the type of ligands bonded to the metal centre as well as their locations The number of atoms bonded is the coordination number The geometrical pattern can be described as a polyhedron where the vertices of the polyhedron are the centres of the coordinating atoms in the ligands 1 The coordination preference of a metal often varies with its oxidation state The number of coordination bonds coordination number can vary from two in K Ag CN 2 as high as 20 in Th h5 C5H5 4 2 One of the most common coordination geometries is octahedral where six ligands are coordinated to the metal in a symmetrical distribution leading to the formation of an octahedron if lines were drawn between the ligands Other common coordination geometries are tetrahedral and square planar Crystal field theory may be used to explain the relative stabilities of transition metal compounds of different coordination geometry as well as the presence or absence of paramagnetism whereas VSEPR may be used for complexes of main group element to predict geometry Contents 1 Crystallography usage 2 Table of coordination geometries 3 Naming of inorganic compounds 4 See also 5 ReferencesCrystallography usage editIn a crystal structure the coordination geometry of an atom is the geometrical pattern of coordinating atoms where the definition of coordinating atoms depends on the bonding model used 1 For example in the rock salt ionic structure each sodium atom has six near neighbour chloride ions in an octahedral geometry and each chloride has similarly six near neighbour sodium ions in an octahedral geometry In metals with the body centred cubic bcc structure each atom has eight nearest neighbours in a cubic geometry In metals with the face centred cubic fcc structure each atom has twelve nearest neighbours in a cuboctahedral geometry Table of coordination geometries editA table of the coordination geometries encountered is shown below with examples of their occurrence in complexes found as discrete units in compounds and coordination spheres around atoms in crystals where there is no discrete complex Coordination number Geometry Examples of discrete finite complex Examples in crystals infinite solids 2 linear nbsp Ag CN 2 in K Ag CN 2 3 Ag in silver cyanide Au in AuI 2 3 trigonal planar nbsp HgI3 2 O in TiO2 rutile structure 3 4 tetrahedral nbsp CoCl4 2 2 Zn and S in zinc sulfide Si in silicon dioxide 3 4 square planar nbsp AgF4 2 CuO 3 5 trigonal bipyramidal nbsp SnCl5 3 5 square pyramidal nbsp InCl5 2 in N CH2CH3 4 2 InCl5 2 6 octahedral nbsp Fe H2O 6 2 2 Na and Cl in NaCl 3 6 trigonal prismatic nbsp W CH3 6 4 As in NiAs Mo in MoS2 3 7 pentagonal bipyramidal nbsp ZrF7 3 in NH4 3 ZrF7 3 Pa in PaCl57 capped octahedral nbsp MoF7 5 La in A La2O37 capped trigonal prismatic nbsp TaF7 2 in K2 TaF7 3 8 square antiprismatic nbsp TaF8 3 in Na3 TaF8 3 Zr H2O 8 4 aqua complex 6 Thorium IV iodide 3 8 dodecahedral note whilst this is the term generally used the correct term is bisdisphenoid 3 or snub disphenoid as this polyhedron is a deltahedron nbsp Mo CN 8 4 in K4 Mo CN 8 2H2O 3 Zr in K2 ZrF6 3 8 bicapped trigonal prismatic nbsp ZrF8 4 7 PuBr3 3 8 cubic Caesium chloride calcium fluoride8 hexagonal bipyramidal nbsp N in Li3N 3 8 octahedral trans bicapped Ni in nickel arsenide NiAs 6 As neighbours 2 Ni capping 8 8 trigonal prismatic triangular face bicapped Ca in CaFe2O4 3 9 tricapped trigonal prismatic nbsp ReH9 2 in potassium nonahydridorhenate 2 Th H2O 9 4 aqua complex 6 SrCl2 6H2O Th in Rb Th3F13 3 9 capped square antiprismatic nbsp Th tropolonate 4 H2O 2 clarification needed La in LaTe2 3 10 bicapped square antiprismatic Th C2O4 4 2 2 11 Th in ThIV NO3 4 H2O 3 NO 3 is bidentate 2 12 icosahedron nbsp Th in Th NO3 6 2 ion in Mg Th NO3 6 8H2O 3 12 cuboctahedron nbsp ZrIV h3 BH4 4 atoms in fcc metals e g Ca 3 12 anticuboctahedron triangular orthobicupola nbsp atoms in hcp metals e g Sc 3 12 bicapped hexagonal antiprismatic U BH4 4 2 Naming of inorganic compounds editIUPAC have introduced the polyhedral symbol as part of their IUPAC nomenclature of inorganic chemistry 2005 recommendations to describe the geometry around an atom in a compound 9 IUCr have proposed a symbol which is shown as a superscript in square brackets in the chemical formula For example CaF2 would be Ca 8cb F2 4t where 8cb means cubic coordination and 4t means tetrahedral The equivalent symbols in IUPAC are CU 8 and T 4 respectively 1 The IUPAC symbol is applicable to complexes and molecules whereas the IUCr proposal applies to crystalline solids See also editMolecular geometry VSEPR Ligand field theory Cis effect Addition to pi ligandsReferences edit a b c J Lima de Faria E Hellner F Liebau E Makovicky E Parthe 1990 Report of the International Union of Crystallography Commission on Crystallographic Nomenclature Subcommittee on the Nomenclature of Inorganic Structure Types Acta Crystallogr A 46 1 11 doi 10 1107 S0108767389008834 a b c d e f g h i j k l Greenwood Norman N Earnshaw Alan 1997 Chemistry of the Elements 2nd ed Butterworth Heinemann ISBN 978 0 08 037941 8 a b c d e f g h i j k l m n o p q r s t u v Wells A F 1984 Structural Inorganic Chemistry 5th edition Oxford Science Publications ISBN 0 19 855370 6 Housecroft C E Sharpe A G 2004 Inorganic Chemistry 2nd ed Prentice Hall p 725 ISBN 978 0 13 039913 7 Kaupp Martin 2001 Non VSEPR Structures and Bonding in d 0 Systems Angew Chem Int Ed Engl 40 1 3534 3565 doi 10 1002 1521 3773 20011001 40 19 lt 3534 AID ANIE3534 gt 3 0 CO 2 PMID 11592184 a b Persson Ingmar 2010 Hydrated metal ions in aqueous solution How regular are their structures Pure and Applied Chemistry 82 10 1901 1917 doi 10 1351 PAC CON 09 10 22 ISSN 0033 4545 Jeremy K Burdett Roald Hoffmann Robert C Fay 1978 Eight Coordination Inorganic Chemistry 17 9 2553 2568 doi 10 1021 ic50187a041 David G Pettifor Bonding and Structure of Molecules and Solids 1995 Oxford University Press ISBN 0 19 851786 6 NOMENCLATURE OF INORGANIC CHEMISTRY IUPAC Recommendations 2005 ed N G Connelly et al RSC Publishing http www chem qmul ac uk iupac bioinorg Retrieved from https en wikipedia org w index php title Coordination geometry amp oldid 1173976525, wikipedia, wiki, book, books, library,

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