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4. Naming of Ambidentate ligands :-
| 1. | NC- ----> | cynido/cyno or cynido - C |
| CN- ----> | isocynido or cynido - N | |
| 2. | ONO- ----> | nitrito or nitroto - O |
| OO-N ----> | nitro or nitrito - N | |
| 3. | NCO- ----> | cynato or cynato - O |
| OCN- ----> | isocynito or cynato - N | |
| 4. | NCS- ----> | thiocynato or thiocynato - S |
| SCN- ----> | isothiocynato or thiocynato - N |
| K4[Fe(CN)6] | Potassium hexacynidoferrate(ii) | |
| [Co(en)3]Cl3 | Tris(ethylenediamine)cobalt(iii)chloride | |
| [Fe(H2O)5NO]SO4 | Pentaaquanitrosoniumiron(i)sulphate | |
| Na2[Fe(CN)5NO] | Sodium heptacynidonitrisoniumferrate(ii) | |
| K2[HgI4] | Potassium tetraiodidomercurate(ii) | |
| [Fe(en)2ClBr]NO3 | Bromochlorobis(ethylenediamine)iron(iii)nitrate | |
| [Ni(CO)4] | Tetracarbonylnickel | |
| Li[AlH4]SO4 | Lithium tetrahydridoaluminate(iii) | |
| H2[PtCl6] | Hexachloroplatenic acid | |
| H[AuCl4] | Tetrachloroauric acid | |
| CuSO4.5H2O water of crystallisation [Cu(H2O)4]SO4.H2O | Tetraaquacuprate(ii)sulphate monohydrate | |
| FeSO4.7H2O [Fe(H2O)6]SO4.H2O | Hexaaquaferrate(ii)sulphate monohydrate | |
| [(NH3)4PtCl2Pt(NH3)4](SO4)3 |
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| Note :- In case of breezing ligands, prefix 'u (mu)' is attached. In last example, Cl2 act as breezing ligand with both Pt. |
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------------------:Hybridisation of Coordination Compound :-------------------
-:Crystal field theory :-
- In presence of ligands, degeneracy of 5 d orbitals destroy said to be Crystal field splitting.
- Magnitude of Crystal field splitting depend on the nature of ligands.
According to Spectrochemical series, ligands are of two type :-
- Strong field ligand :- They pair up unpaired electrons present in inner d-subshell.
- Weak field ligand :- They do not disturb the original configuration of inner d-subshell. They do not pair up unpaired electrons.
According to Spectrochemical series,
Weak field
ligand -I- < Br- < SCN- < Cl- < S2- < NO3- < F- < OH- < CH3OO- < C2O42- < H2O Strong field
ligands -NCS- < edta4- < NH3 < py < en < dipy < NO2- < CN- < CO Weak field
ligands -O2- NO+ PPH3 Strong field ligands - dmg- gly-
- Possible geometry of Coordination number 6 is octahedral.
- Bond angle will be 90o and 180o.
- Ligands will approches axially so, energy of 'eg' set of orbitals will increases more than energy of 't2g' shell of orbitals.
In presence of any ligand, 1st electron goes in dxy, 2nd electron goes to dyz, 3rd electron goes to dx orbital, but in case of Strong field ligand, 4th electron will pair up or goes in dxy, 5th electron will pair up in dyz, 6th electron will pair up in dx orbitals. After that 7th electron goes to dx2y2, 8th electron goes to dz2, 9th electron will pair up or goes in dx2y2 and 10th electron will pair up or goes in dz2 orbital. It means, in presence of Strong field ligand, pairing of electrons take place.
But in presence of Weak field ligand, first all orbitals will filled up by one electron each. It means if 5 electrons are present, then all five orbitals will contain one electron each. After that if 6th electron will come, then it will pair up in dxy orbital (1st orbital) and so on.
d-subshell Strong field
LigandHybridization Weak field
LigandHybridization d1 t2g1 eg0 d2sp3 t2g1 eg0 d2sp3 d2 t2g2 eg0 t2g2 eg0 d3 t2g3 eg0 d2sp3 t2g3 eg0 d2sp3 d4 t2g4 eg0 t2g3 eg1 sp3d2 d5 t2g5 eg0 t2g3 eg2 d6 t2g6 eg0 t2g4 eg2 d7 t2g6 eg1 sp3d2 t2g5 eg2 sp3d2 d8 t2g6 eg2 t2g6 eg2 d9 t2g6 eg3 t2g6 eg3 d10 t2g6 eg4 t2g6 eg4 Result -> configuration in d1, d2, d3, d8, d9, d10 doesn't depend on the nature of ligand.
--: Calculation of Magnetic Moment :--
if n = number of unpaired electron, then
Magnetic Moment (mu), u = {n(n+2)}1/2
Total spin (s) = n * 1/2
High spin = higher number of unpaired electron
Low spin = lower number of unpaired electrond-subshell Strong field Ligand Weak field Ligand unpaired electron High or Low spin unpaired electron High or Low spin d1 1 Not define 1 Not define d2 2 Not define 2 Not define d3 3 Not define 3 Not define d4 2 Low spin 4 High spin d5 1 Low spin 5 High spin d6 0 Low spin 4 High spin d7 1 Low spin 3 High spin d8 2 Not define 2 Not define d9 1 Not define 1 Not define d10 0 Not define 0 Not define High spin and Low spin is defined only for d4, d5, d6 and d7. For Strong Field Ligand, it is Low spin and for Weak Field Ligand, it is High spin. --: Calculation of Hybridization :--
Note :-- Only 'eg' set of (n-1)d orbital can be used in Hybridization.
Example :--
K3[Fe(CN)6] [Fe(SCN)6]-3 26Fe = [Ar] 4s2 3d6 26Fe = [Ar] 4s2 3d6 Primary valancy = +3 Primary valancy = +3 26Fe+3 = [Ar] 4s0 3d5 26Fe+3 = [Ar] 4s0 3d5 
As CN- is a strong field ligand, it will
pair up 4 electrons in 3d orbital.
1 remain unpair because there is no
more single electron for pairing.As SCN- is a weak field ligand, it does not change the original configuration of electrons. 5 electrons remain unpaired. All electron will lie in 't2g' set.
t2g 5 eg03 electron electron will lie in 't2g' and 2 electron will lie in 'eg' set.
t2g 3 eg 2
On pairing of electron, 2 orbitals of
3d will contain 2-2 electrons (paired electrons) and 1 orbital contain 1 electron.
Here 2 orbitals are vacant which accept
loan pair given by ligand. So 2 orbitals which accept loan pair will participate in Hybridization.All 5 orbitals of 3d will contain 1 unpaired electron. Here no orbital is vacant, so no one will accept loan pair given by ligand. So none of 3d orbital will participate in Hybridization. 
Hybridization = d2sp3 Hybridization = sp3d2 unpaired electron = 1 unpaired electron = 5 Magnetic Moment, u = {n(n+2)}1/2
u = {1(1+2)}1/2 = 31/2Magnetic Moment, u = {n(n+2)}1/2
u = {5(5+2)}1/2 = (35)1/2Low spin High spin Complex d-subshell Hybridization unpaired
electronMagnetic
MomentHigh or
Low spin[Fe(en)3]+2 d6 d2sp3 0 0 Low spin [CoF6]-3 d6 sp3d2 4 (24)1/2 High spin [Fe(en)2ClBr]NO3 d5 d2sp3 1 31/2 Low spin [Ni(H2O)6]+2 d8 sp3d2 2 81/2 Not define [Fe(H2O)6]+3 d5 sp3d2 5 (35)1/2 High spin [V(H2O)6]+3 d2 d2sp3 2 81/2 Not define [Cr(NH3)6]+3 d3 d2sp3 3 151/2 Not define [Co(en)3]+2 d7 d2sp3 1 31/2 Low spin Transference of electron in d7 :- like in [Co(en)3]+2
- Condition for transference are :-
- Only one electron is transferred
- All the ligands must be strong filled ligand
- After transference, orbital left vacant must be used in hybridization.
After transference, electron of 3d7 will goes to or lie in 4d1 in case of [Co(en)3]+2. Hence two orbitals or 'eg' set is vacant in case of [Co(en)3]+2.
Hence, Hybridization is d2sp3[Mn(H2O)6]+2 d5 sp3d2 5 (35)1/2 High spin Na2[Fe(CN)5NO] d6 d2sp3 0 0 Low spin [Fe(NH3)6]+3 d5 d2sp3 1 31/2 Low spin [Co(NO2)6]-3 d6 d2sp3 0 0 Low spin -: Limitation of Crystal Field Theory :-
- NH3 is a Weak Field Ligand with Fe+2 and Mn+2 if coordination number is 6.
- [Cr(H2O)6]+3, hybridization of this compound should be 'd2sp3', but actual hybridization of this compound is 'sp3d2'.
- For 4-d and 5-d series elements, all the ligands are acting as Strong Field Ligand due to their higher Z-effective
.
- For Co+3, if coordination number is 6, then all the ligands written on the right side of the ' floride ' are Strong Field Ligand.
Case : 1- In Presence of Strong Field Ligands :-
- Possible geometry = Square Planar.
- Hybridization = dsp2
Orbitals Hybridization 
d0 - d8 dsp2 d9 dsp2
(transference of electron)d10 sp3 Case : 2
- In Presence of Weak Field Ligands :-
- Possible Geometry = Tetrahedral.
- Hybridization = d3s / sp3.
Orbitals Hybridization 
d0, d1, d2 d3s d3 ... d10 sp3 Complex d-subshell Hybridization Unpaired
electron[MnCl4]-2 d5 sp3 5 [Ni(CN)4]-2 d8 dsp2 0 [NiCl4]-2 d8 sp3 2 [Cu(NH3)4]+2 d9 dsp2 1 [Cu(CN)4]-3 d10 sp3 0 [PtCl4]-2 d8 dsp2 0 [Zn(NH3)4]+2 d10 sp3 0 [Ni(en)Cl2] d8 dsp2 0 [Ni(PPH3)Cl2] d8 sp3 2 [Ni(dmg)2] d8 dsp2 0 [CoCl4]-2 d7 sp3 3 [Rh(PPH3)Cl]
Wilkinson's catalystd8 dsp2 0 [Ni(CO)4] d10 sp3 0 NOTE :- s electron are remaining if any, are transferred to d-subshell. - Possible geometry of Coordination number 6 is octahedral.
