1. Understanding the Absorption Electronic Spectra of Coordination Compounds at greater depth
Ligand Field Theory
Chapter 20

2. Review of the Previous Lecture
Learned how to more specifically define multielectron systems
Introduced new quantum numbers (L and S)
Defined atomic states and how to label them with Russel-Saunders Term Symbols
Characterized the energy of atomic states using Hund’s rules

3. 1. Ligand Field Theory
Ligand field theory incorporates molecular orbital theory and treats the ligand field not as a purely electrostatic system.
Electronic transitions will be reexamined by considering the atomic states of multielectron systems, focusing on transition metals
Allowed transitions will be examined in both weak and strong field coordinations

4. 2. Orgel diagrams to evaluate d-d electronic transitions
A. Orgel diagrams are correlation diagrams that correlate orbital energies as they vary with ligand field strengths
Consider the ground atomic state and examine what happens in the weak field limit
i.e. d1
S = ½
Multiplicity = 2S + 1 = 2
L = 2
2D Ground State
Atomic State L S P 1 D 2 F 3 E +2 +1 -1 -2
Absence of ligands

5. 2. Orgel diagrams to evaluate d-d electronic transitions
i.e. d1 eg E
“Δoct”
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 2D
S = ½
Multiplicity = 2S + 1 = 2; 2T2g

6. 2. Orgel diagrams to evaluate d-d electronic transitions
i.e. d1
This single electron can be in any of the three t2g orbitals and so this electronic situation describes a triply degenerate state. eg E
“Δoct”
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 2D
S = ½
Multiplicity = 2S + 1 = 2; 2T2g

7. 2. Orgel diagrams to evaluate d-d electronic transitions
i.e. d1
Electron transition eg eg E
“Δoct”
t2g
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 2D
2T2g
2Eg
The electron can be in either eg orbital.
Double degeneracy.

8. 2. Orgel diagrams to evaluate d-d electronic transitions
i.e. d1
Electron transition eg eg E
“Δoct”
t2g
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 2D
2T2g
2Eg
Spin Allowed transition

9. 2. Orgel diagrams to evaluate d-d electronic transitions
“Δoct” E
t2g eg
Absence of ligands +2 +1 -1 -2
Octahedral Field
2T2g
2Eg
Electron transition 2D
Expect one absorbance
in the UV-Vis spectrum
d1 Octahedral
Orgel Diagram

10. A d1 absorbance in reality
A Z-in Jahn-Teller distortion applies to a d1 electron configuration in an octahedral field:
i.e. [Ti(H2O)6] Ti3+ B A
Electronic
absorbance
Ground State
dz2
dz2
dz2
dx2 – y2
dx2 – y2
dx2 – y2 E
dxz
dyz
dxz
dyz
dxz
dyz
dxy
dxy
dxy B A

11. Components in an octahedral field (Splitting)
2B. Different atomic states produce different components in an octahedral field
Atomic State
Components in an octahedral field (Splitting) S
A1g P
T1g D
T2g + Eg F
A2g + T2g + T1g
d1 Octahedral
Orgel Diagram

12. 2C. d2 Octahedral Orgel Diagram (Partial)
S = 1
Multiplicity = 2S + 1 = 3
L = (+2x1) + (+1x1) = 3
3F Ground State
Atomic State L S P 1 D 2 F 3 E +2 +1 -1 -2
Absence of ligands

13. 2C. d2 Octahedral Orgel Diagram (Partial)
For d2 the atomic states are 3F, 3P, 1G, 1D, and 1S 1S 1D
The d2 Orgel Diagram would consist of all of these atomic states but we will only focus on the ground state and how it splits in an octahedral field. E 1G 3P 3F

14. 2C. d2 Octahedral Orgel Diagram (Partial)
Atomic State
Components in an octahedral field (Splitting) S
A1g P
T1g D
T2g + Eg F
A2g + T2g + T1g E +2 +1 -1 -2
Absence of ligands
3F Ground State

15. 2C. d2 Octahedral Orgel Diagram (Partial)
1st Excitation
2nd Excitation eg eg eg E
“Δoct”
t2g
t2g
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 3F
3T1g
3T2g
3A2g

16. 2C. d2 Octahedral Orgel Diagram (Partial)
1st Excitation
2nd Excitation eg eg eg E
“Δoct”
t2g
t2g
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 3F
3T1g
3T2g
3A2g
Energy
3A2g
Partial
d2 Octahedral
Orgel Diagram
Considering only ground
Atomic State
2nd Excitation
3T2g 3F
1st Excitation
3T1g
Increasing Δoct

17. 2D. d3 Octahedral Orgel Diagram (Partial)+2 +1 -1 -2
Absence of ligands 4F
For d3 the atomic states are
4F, 4P, 2H, 2G, 2F, 2D, 2D, and 2P
Increasing Δoct

18. 2D. d3 Octahedral Orgel Diagram (Partial)+2 +1 -1 -2
Absence of ligands 4F
For d3 the atomic states are
4F, 4P, 2H, 2G, 2F, 2D, 2D, and 2P
States of the same term symbols cannot
cross. Orbital mixing.
Lower energy state is stabilized
Higher energy state is destabilized
Increasing Δoct

19. 2E. d9 Octahedral Orgel Diagram
Excitation eg eg E
“Δoct”
t2g
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 2D

20. 2E. d9 Octahedral Orgel Diagram
Positive Hole Concept
Excitation eg eg E
“Δoct”
t2g
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 2D
2Eg
2T2g

21. 2E. d9 Octahedral Orgel Diagram
Excitation eg eg E
“Δoct”
t2g
t2g +2 +1 -1 -2
Absence of ligands
Octahedral Field 2D
2Eg
2T2g
Energy
2T2g
Inverse of d1 Octahedral Orgel Diagram 2D
2Eg
Increasing Δoct

22. 2F. Inverse Relationship of Orgel Diagrams
It turns out d10-n (Oh or Td) Orgel diagrams are inverse of dn (Oh or Td) Orgel diagrams.

23. 2G. Determining Δoct
Determining Δoct can be complicated using Orgel Diagrams when there are allowed transitions arising from different initial atomic states.
Consider a more detailed d2 octahedral Orgel Diagram

24. 2G. Determining Δoct
To determine Δoct, need to approximate the value of the Racah parameter B
A measure of the splitting of the initial atomic states
B accounts for electron-electron repulsions

25. 3. Tanabe-Sugano Diagrams
Tanabe-Sugano diagrams provide similar information as Orgel diagrams but allow you to consider d-d electronic transitions in the weak and strong field limits.
d1 Octahedral
Orgel Diagram
d1 Octahedral
Tanabe Sugano Diagram E B
2Eg 2D
2T2g
Δoct B

26. 3A. Using Tanabe-Sugano Diagrams to determine Δoct
Consider d3 in an octahedral field.
3rd Excitation eg +2 +1 -1 -2
t2g
1st Excitation
2nd Excitation
4P (One microstate example) E
4T1g
Hard to Represent eg eg eg +2
t2g
t2g
t2g +1 -1 -2
Absence of ligands
Octahedral Field 4F
4A2
4T2
4T1

27. 3A. Using Tanabe-Sugano Diagrams to determine Δoct
3rd Excitation eg +2 +1 -1 -2
t2g
1st Excitation
2nd Excitation
4P (One microstate example)
4T1g
Hard to Represent E eg eg eg +2
t2g
t2g
t2g +1 -1 -2
Absence of ligands
Octahedral Field 4F
4A2g
4T2g
4T1g

28. 3A. Using Tanabe-Sugano Diagrams to determine Δoct

29. 3A. Using Tanabe-Sugano Diagrams to determine Δoct

30. 3A. Using Tanabe-Sugano Diagrams to determine Δoct

31. 3A. Using Tanabe-Sugano Diagrams to determine Δoct

32. 3A. Using Tanabe-Sugano Diagrams to determine Δoct
To determine Δoct, you first need to perform a trial and error process of determining a value for Δoct/B on the Tanabe-Sugano diagram that will give you comparable energy difference ratios for the allowed transitions as your experimental values.

33. 3B. Tanabe-Sugano Diagrams provide d-d electronic transition information in the weak and strong field
Consider d5 in an octahedral field. E eg +2
t2g +1 -1 -2
Absence of ligands 6S
Weak Field; High Spin
S = 5/2
Strong Field; Low Spin
S = 1/2
2T2g
6A1g

34. d5 Octahedral Tanabe-Sugano Diagram
Weak field (high spin)
6A1g is the ground state
No spin-allowed transitions
But they do occur; ϵ < 1 M-1cm-1

35. d5 Octahedral Tanabe-Sugano Diagram
Strong field (low spin)
2T2g is the ground state
Four allowed transitions
2T2g to 2A2g or 2T2g to 2T1g
2T2g to 2Eg
2T2g to 2T2g (2I)
2T2g to 2A1g
Spin-allowed transitions,
ε = M-1cm-1
Four absorbances but due to resolution may not actually see them

36. 4. Charge transfer electronic transitions
Charge transfer e- transitions are Spin and Laporte allowed; ε > 1,000 M-1cm-1
Typically observed in the UV range of light
Occur at higher energy than d-d electronic transitions
Ligand to metal charge transfer (LMCT)
Transfer of an electron from an orbital with primarily ligand character to one with primarily metal character
Can be observed with π donor ligands M L e-

37. Revisit Molecular Orbital Diagram including π interaction with Weak Field Ligands
[CoF6]3-
High spin, S = 2
Co3+ ; d6

38. Revisit Molecular Orbital Diagram including π interaction with Weak Field Ligands
[CoF6]3-
High spin, S = 2
LMCT Bands
Co3+ ; d6

39. 4. Charge transfer electronic transitions
B. Metal to ligand charge transfer (MLCT)
Transfer of an electron from an orbital with primarily metal character to one with primarily ligand character
Can be observed with π acceptor ligands M L e-

40. Revisit Molecular Orbital Diagram including π interaction with Strong Field Ligands
[Co(CO)6]3+
MLCT Bands
Low spin, S = 0
Co3+ ; d6