2P32 – Principles of Inorganic Chemistry Dr. M. Pilkington Lecture 3 - Classification and Nomenclature 1. Ligand Classification: 2. Coordination Chemistry and Ligands Monodentate Ligands Ambidentate Ligands Bridging Ligands – Biological Applications Multi/Polydentate Chelating Ligands Naming Metal Complexes Rodgers Chapt 2. Coordination Chemistry Alfred Werner (1866-1919) 1893, age 26: coordination theory Nobel prize for Chemistry, 1913 Addition of 6 mol NH3 to CoCl3(aq) Coordination compound/complex. 3+ NH3 H N M H3N H3N H H N forms a coordinate covalent bond to the metal Co NH3 NH3 3Cl– (counterion) NH3 ligand (coordination sphere) 1 1. Ligand Classification Ligand – Lewis base (electron pair donor) that is bonded to a metal ion. Ligands are anionic or neutral. H ]3+ i.e. [Fe(NH3)6 Metal Complex Fe N H H Ligand - Lewis Base Has one pair of electrons :NH3 The NH3 shares its electron with the Fe(III) metal ion. Classes of Ligands 1. Monodentate Ligands “one toothed” – bind to a metal ion through a single donor site. For example :NH3 is a monodentate ligand. Co3+ :NH3 Fe3+ Cl Fe2+ C N 2 2. Bridging Ligands Bind to two or more metal ions simultaneously. For Example: O2Cl Fe C N 2 (H2O)5Fe Co3+ O Cl neutral ligand Fe(H2O)5 Co3+ Fe [(NC)5Fe(III)CNFe(III)(CN)5]5- Fe can exist in number of oxidation states. A biologically important metal ion. A Biological Application of Fe Iron-sulfur proteins are proteins characterized by the presence of iron-sulfur clusters containing sulfide-linked iron centers in variable oxidation states. Structural motifs In almost all Fe-S proteins, the Fe centers is tetrahedral and the thiolato sulfur centers, from cysteinyl residues, are terminal ligands. The sulfide groups are either two- or threecoordinated. A common motif features a four iron ions and four sulfide ions placed at the vertices of a cubane-type structure. 4Fe-4S clusters 3 Aconitase - aconitate hydratase; is an enzyme that catalyses the stereo-specific isomerization of citrate to isocitrate via cisaconitate in the tricarboxylic acid cycle, a non-redox-active process. Illustration of pig aconitase in complex with the [Fe4S4] cluster. The protein is colored by secondary structure, and iron atoms are blue and the sulfur red. 3. Ambidentate Ligands Two kinds of binding sites – the ligand can bind through one or the other but not both simultaneously. :C Ambidentate N: Fe2+ CN It is not possible for N to bind to the same Fe2+ NO2- O N O lone pairs on O and N can bind through either lone pair :N C S Thiocyanide ligand can bind through S or N but not both at the same time to one metal ion. You will need to be able to draw the Lewis acid structures correctly so you can figure out how a ligand will bind. 4 4. Multi-/Polydentate Chelating Ligands Multidentate – “multitooth”; chelating - “crab” claw Ligands that are bound to a metal through several donor sites. Chelate – “Chelos” (greek) meaning “crab” (crabs grab their food with two claws, in the same way a metal can be attracted by two lone pairs from different groups on the same ligand). Example 1. Ethylenediamine H2NCH2CH2NH2 Forms a 5-membered chelate ring; you can think of it havings “2 claws” coming in to grab the metal. 3 H2C H 2 N H 4 CH2 H N 5 H M 1 bidentate "two-toothed" 5-membered chelate ring The Chelate Effect For a given metal ion, the thermodynamic stability of a chelated complex involving bidentate or polydentate ligands is greater than that of a complex containing a corresponding number of comparable monodentate ligands. This is called the chelate effect. 5-membered rings are more stable than 6, 4-membered rings (or smaller) are not stable due to steric strain. 5 Example 2. Ethylenediaminetetraacetate (ETDA) O O O C C CH2 CH2 O O M NCH2CH2N O C CH2 O N CH2 O C O N O O O [M(EDTA)]n- two Nitrogen's and four Oxygens bond to a single metal ion - Hexadentate Ligand. When we draw the ligand chelated to the metal ion we do not draw all of the carbons. - O Cr O N N Cr O O O N [Cr(edta)]– 6 Examples of Multidentate Chelating Ligands Example 3. β-Diketones α β R C O 2,4-pentadione, Ketone group on β carbon Ketone form CH2 C R' diketo O equimolar with another form R O enol R Enol form the alcohol has an OH ending CH C R' C OH C CH C R' O O the enol form can easily dissociate, i.e. loose a H enolate anion β-Diketones – bidentate ligands e.g. R= CH3 Acetylacetone H C R R' H C R C R' C O O O O M M where R = CH3 acetylacetone R' R Chelate Ring O O M delocalized electrons in the double bond 7 Make sure you can draw the structures and metal complexes of all of the ligands on your ligand sheet. Problem – Test 2007 worth 8 marks 1. Draw Lewis structures for the following ligands: (i) Pyridine C6H5N (2 marks) (ii) Nitrato NO3- (2 marks) (iii) Nitro NO2- (2 marks) Which ligand(s) above is/are ambidentate and why? (2 marks) 2. Naming Metal Complexes – refer to handout and Rodgers textbook (pg 20-26) for rules and examples. 1. For complex ions write the cation first and anion last e.g. K2[PtCl4] – Potassiumtetrachloroplatinate. (note you do not use the prefix mono, di or tri etc.. here to indicate the number of cations) 2. Name the ligands first in alphabetical order, the metals last. 3. Prefixes to indicate numbers. (di, tri, tetra, penta, hexa etc…) for all monoatomic ligands, polyatomic ligands with short names and neutral ligands with special names. (see Table 2.4 Rodgers). 4. Prefixes bis-, tris-, tetrakis-, pentakis-, hexakis- for ligands whose names contain a prefix of the first type, neutral ligands without special names, ionic ligands with particularly long names. 8 For example: [Cr(H2O)4Cl2]+ - tetraaquodichlorochromium(III) ion. [Cr(NH2CH2CH2NH2)3]3+ - tris(ethylenediammine)chromium(III) ion. Note the parenthesis around the organic ligand name. 5. If the anion is complex, add the suffix –ate to the name of the metal. If the symbol comes from latin/greek, then we go back to the latin/greek for the name of the anion. 6. Put the oxidation state in Roman numerals in parantheses after the name of the central metal ion. 7. Practice to get the hang of this – Examples from Rodgers and Practice Handout. For example: [CoCl4]2- - tetrachlorocobaltate(II) ion [Fe(CN)6]4- - hexacyanoferrate(II) ion Ligand Names Neutral Ligands - they have the same name as the molecule with 4 exceptions. Molecule Name Ligand Name NH3 Ammonia Ammine H2O Water Aquo CO Carbon monoxide Carbonyl NO Nitric oxide Nitrosyl Anionic Ligands (end in –ide or –e) – add –o Ion Ligand Name ClChloride Chloro OHHydroxide Hydroxo 2SO4 Sulfate Sulfate and so on …… 9 Naming Metal Complexes Fe Cu Ar Au Sn Pb Hg Greek/Latin Ligand ferrum ferrate cuprum cuprate argentum argentate aurum aurate stannum stannate plumbum plumbate hydrorgyrum mercurate Bridging Ligands – use μ to indicate a bridge. If there is more than one of a given bridging ligand, the prefix indicating the number of ligands is placed after the μ. If there is more than one different bridging ligands, they are given in alphabetical order. For example: O22- peroxide O O (H3N)4CoIII 2- CoIII(NH3)4 NH2 amide Tetraamminecobaltate(III)-μ-amido-μ-peroxo-tetraamminecobaltate(III) ion 10 Naming Metal Complexes Examples: [Co(NH3)6]3+ hexaamminecobalt(III) ion. [PtCl2(NH3)2] diamminedichloroplatinum(II) ion. [Fe(CN)6]4- hexacyanoferrate(II) ion. [Fe(H2O)6]2+ hexaaquoiron(II) ion. Problem - Test 2007 Name the compounds: 1. Na[Co(H2NCH2CH2NH2)(C2O4)ClBr] (2 marks) 2. [Zn(EDTA)]2- (2 marks) 11
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