1. Coordination Chemistry Electronic Spectra of Metal Complexes

2. Electronic spectra (UV-vis spectroscopy)

3. Electronic spectra (UV-vis spectroscopy)hn DE

4. The colors of metal complexes

6. Electronic configurations of multi-electron atoms
What is a 2p2 configuration?
n = 2; l = 1; ml = -1, 0, +1; ms = ± 1/2
Many configurations fit that description
These configurations are called microstates
and they have different energies
because of inter-electronic repulsions

7. Electronic configurations of multi-electron atoms
Russell-Saunders (or LS) coupling
For the multi-electron atom
L = total orbital angular momentum quantum number
S = total spin angular momentum quantum number
Spin multiplicity = 2S+1
ML = ∑ml (-L,…0,…+L)
MS = ∑ms (S, S-1, …,0,…-S)
For each 2p electron
n = 1; l = 1
ml = -1, 0, +1
ms = ± 1/2
ML/MS define microstates and L/S define states (collections of microstates)
Groups of microstates with the same energy are called terms

8. Determining the microstates for p2

9. Spin multiplicity 2S + 1

10. Determining the values of L, ML, S, Ms for different terms2P

11. One remaining microstate
Classifying the microstates for p2
Largest ML is +2,
so L = 2 (a D term)
and MS = 0 for ML = +2,
2S +1 = 1 (S = 0) 1D
One remaining microstate
ML is 0, L = 0 (an S term)
and MS = 0 for ML = 0,
2S +1 = 1 1S
Next largest ML is +1,
so L = 1 (a P term)
and MS = 0, ±1/2 for ML = +1,
2S +1 = 3 3P
Spin multiplicity = # columns of microstates

12. Next largest ML is +1,
so L = 1 (a P term)
and MS = 0, ±1/2 for ML = +1,
2S +1 = 3 3P
Largest ML is +2,
so L = 2 (a D term)
and MS = 0 for ML = +2,
2S +1 = 1 (S = 0) 1D
ML is 0, L = 0
2S +1 = 1 1S

13. Energy of terms (Hund’s rules)
Lowest energy (ground term)
Highest spin multiplicity
3P term for p2 case
3P has S = 1, L = 1
If two states have
the same maximum spin multiplicity
Ground term is that of highest L

14. Determining the microstates for s1p1

15. Determining the terms for s1p1
Ground-state term

16. Coordination Chemistry Electronic Spectra of Metal Complexes cont.

17. Electronic configurations of multi-electron atoms
Russell-Saunders (or LS) coupling
For the multi-electron atom
L = total orbital angular momentum quantum number
S = total spin angular momentum quantum number
Spin multiplicity = 2S+1
ML = ∑ml (-L,…0,…+L)
MS = ∑ms (S, S-1, …,0,…-S)
For each 2p electron
n = 1; l = 1
ml = -1, 0, +1
ms = ± 1/2
ML/MS define microstates and L/S define states (collections of microstates)
Groups of microstates with the same energy are called terms

18. before we did: p2 ML & MS Microstate Table States (S, P, D)
Spin multiplicity
Terms
3P, 1D, 1S
Ground state term 3P

19. For metal complexes we need to consider
d1-d10 d2
3F, 3P, 1G, 1D, 1S
For 3 or more electrons, this is a long tedious process
But luckily this has been tabulated before…

20. Transitions between electronic terms will give rise to spectra

21. Selection rules (determine intensities)
Laporte rule
g  g forbidden (that is, d-d forbidden)
but g  u allowed (that is, d-p allowed)
Spin rule
Transitions between states of different multiplicities forbidden
Transitions between states of same multiplicities allowed
These rules are relaxed by molecular vibrations, and spin-orbit coupling

22. Group theory analysis of term splitting

23. High Spin Ground States
An e electron superimposed on a spherical distribution energies reversed because tetrahedral
High Spin Ground States dn
Free ion GS
Oct. complex
Tet complex d0 1S
t2g0eg0
e0t20 d1 2D
t2g1eg0
e1t20 d2 3F
t2g2eg0
e2t20 d3 4F
t2g3eg0
e2t21 d4 5D
t2g3eg1
e2t22 d5 6S
t2g3eg2
e2t23 d6
t2g4eg2
e3t23 d7
t2g5eg2
e4t23 d8
t2g6eg2
e4t24 d9
t2g6eg3
e4t25
d10
t2g6eg4
e4t26
Holes in d5 and d10, reversing energies relative to d1
A t2 hole in d5, reversed energies, reversed again relative to octahedral since tet.
Holes: dn = d10-n and neglecting spin dn = d5+n; same splitting but reversed energies because positive.
Expect oct d1 and d6 to behave same as tet d4 and d9
Expect oct d4 and d9 (holes), tet d1 and d6 to be reverse of oct d1

24. D d1  d6 d4  d9 Orgel diagram for d1, d4, d6, d9 T2 E
d1, d6 tetrahedral Eg
T2g
d1, d6 octahedral
d4, d9 tetrahedral
or T2
or E
T2g or
Eg or
d4, d9 octahedral
Energy D D D
ligand field strength

25. Ligand field strength (Dq)
Orgel diagram for d2, d3, d7, d8 ions
Energy
A2 or A2g
T1 or T1g P
T1 or T1g
T2 or T2g
T1 or T1g F
T2 or T2g
T1 or T1g
A2 or A2g
d2, d7 tetrahedral d2, d7 octahedral
d3, d8 octahedral d3, d8 tetrahedral
Ligand field strength (Dq)

26. d2
3F, 3P, 1G, 1D, 1S
Real complexes

27. Tanabe-Sugano diagrams

28. Electronic transitions and spectra

29. Other configurations d3 d1 d9 d2 d8

30. Other configurations d3
The limit between
high spin and low spin

31. Determining Do from spectra
One transition allowed of energy Do

32. Determining Do from spectra
mixing
Lowest energy transition = Do

33. E (T1gA2g) - E (T1gT2g) = Do
Ground state mixing
E (T1gA2g) - E (T1gT2g) = Do

34. The d5 case All possible transitions forbidden
Very weak signals, faint color

35. Some examples of spectra

36. Charge transfer spectra
Metal character
LMCT
Ligand character
Ligand character
MLCT
Metal character
Much more intense bands