CHEM 511 Chapter 20 page 1 of 16
Chapter 20
d-metal complexes: electronic structures and
properties
Recall the shape of the d-orbitals...
Electronic structure
Crystal Field Theory: an electrostatic approach to understand d-orbital complexes. It provides
an approximate description of the electronic energy levels that determine the UV and visible
spectra, but does not describe the bonding. It predicts that the d-orbitals will not be degenerate.
d-orbitals split. Why?
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Electronic spectra and split orbitals
Imagine a d1 electron species: Ti(H2O)63+
o is different for every complex, but there are patterns.
The Spectrochemical Series
I-<Br-<S2-<SCN-<Cl-<NO2-<N3
-<F-<OH-<C2O42-<H2O<NCS-<CH3CN<py<NH3<en<bipy<phen
<NO2-<PPh3<CN-<CO
o also depends on the metal
o increases with higher oxidation number
o increases going down a group
Spectrochemical Series for metals (partial list)
Mn2+<Ni2+<Co2+<Fe2+<V2+<Fe3+<Co3+<Mn4+<Mo3+<Rh3+<Ru3+<Pd4+<Ir3+<Pt4+
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Crystal Field Stabilization Energy (CFSE)
The split d-orbitals results in a lowering of the energy for three orbitals (dxy, dxz, dyz) and an
increase in energy for two orbitals (dx2-y2, dz2)—relative to the orbitals in a spherical field
For a d0 metal, Ca2+, Sc3+, Ti4+, CFSE = 0
For a d1 metal (e.g., Ti3+)
For a d2 metal (e.g., V3+)
For a d3 metal (e.g., Cr3+)
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For a d4 metal (e.g., Cr2+)
Which configuration for d4? Depends on placement in the spectrochemical series!
If you have ligands low on the series and metals low on the series, you will generally get
a maximum for unpaired electrons
This is called a high spin complex or a weak field complex
EX. [CrCl6]4-
For ligands high in the series and metals high in the series, you get a low spin complex
(strong field case)
EX. [Ru(NO2)6]3- (what is NO2
- called in this case?)
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What about the in-between cases?
Best to have experimental evidence on unpaired electrons
Generalizations:
o Ligands high on the series and 3d metals = strong field cases
o 4d and 5d metals with just about any ligand = strong field cases
Measuring electron spin
Use a Guoy balance to measure paramagnetism.
Paramagnetism: attraction to a magnetic field due to unpaired
electrons
Diamagnetism: repulsion of a magnetic field by paired electrons
(weaker than paramagnetism)
Can measure the magnetic moment ()
= 2×(S(S+1))½ × B S = spin quantum number (total spin), B = Bohr magneton
Also, = (N(N+2))½ × B N = number of unpaired electrons
EX. The magnetic moment of an octahedral complex for Co2+ is 4.0B. What is the electron
configuration?
http://www.sherwood-scientific.com/msb/msbindex.html
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Tetrahedral complexes
For Td complexes, d-orbitals are split, but opposite of an Oh complex.
See the appropriate character table in the Resource Section of your textbook.
What labels are given to the orbitals? Which are higher in energy?
T is smaller than o because there are fewer ligands
Td complexes are only weak field cases
EX. What is the CFSE for [CoCl4]-?
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Splitting patterns for various geometries of metal complexes. How well does this correlate with
the character tables of the correct point groups?
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The Jahn-Teller Effect
If the ground electronic configuration of a non-linear complex is orbitally degenerate, the
complex will distort so as to remove the degeneracy and achieve a lower energy
w = weak
s = strong
blank = no distortion
Tetragonal distortion and square planar complexes
Distortion of Oh symmetry causes a change in orbital energies—and severe distortion could
cause loss of ligands!
Mainly affects d7, d8, d9 complexes
# of e- 1 2 3 4 5 6 7 8 9 10
high spin W w s w w s
low spin W w w w s s
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Distortion for d8 complexes can be enough to cause spin pairing in the dz2 and you lose the
ligands along the z-axis.
To accomplish this, need a strong field ligand or a strong field metal.
[NiCl4]2-
[Ni(CN)4]2-
[PdCl4]2-
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Ligand Field Theory While crystal field theory is useful in making correlations between experimental evidence (e.g.,
λmax and electron configuration), it doesn’t necessarily explain why—using MO theory can help
explain the “whys”.
Complexes with σ-bonding
As with previous MO theory, there must be matching symmetry for a bond to occur.
What are the symmetries of the metal orbitals in an octahedral field? Let’s assume we have a 3d
metal (see character table).
What symmetries will the ligands adopt?
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What symmetries will overlap in the MO? and as importantly, what doesn’t have the right symmetry?
Build the MO diagram...
eg electrons in complex are not strictly confined to the metal atom
o is still a function of t2g and eg separation.
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Complexes with π-bonding
-orbitals (bonding and antibonding) may form between d-orbitals and (filled) p-orbitals or d-
orbitals and (empty) antibonding orbitals on a ligand
d-orbital and p-orbital
Consider a ligand with a filled p-orbital (called -donor ligands)
Build the MO showing π-bonding between the metal and p-orbitals.
d-orbital and antibonding -orbital
Recall CO (build the MO)
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What orbitals would overlap with the antibonding orbitals in CO?
Build the MO between d-orbitals and antibonding orbitals in the ligands
Δo increases with the following trend:
-donor < weak -donor < no effects < -acceptor
I- < Br- < Cl- < F- < H2O < NH3 < PR3 < CO (this is the spectrochemical series)
Ligands may be neither π-donors nor π-acceptors, but can still be strong σ-donors: CH3-, H-
Skip sections 20.6-20.9
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Thermochemical correlations with crystal/ligand field stabilization energies The data in the table of high and low spin Δoct can be plotted as follows:
This correlation with CFSE (LFSE) is found repeated in several manifestations:
Hydration energy
This graph is for M2+(aq) ions
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Irving-Williams Series
Ranks the stability of M2+ complexes as the following
Ba2+ < Sr2+ < Ca2+ < Mg2+ < Mn2+ < Fe2+ < Co2+ < Ni2+ < Cu2+ > Zn2+
Compare electronic structure of Ni2+ and Cu2+
How many d e-?
What's the expected e- configuration?
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Comparing multiple substitution of NH3 for M(H2O)62+
Lattice energy
In a MCl2 lattice, we find the following lattice energies.
Use CFSE/LFSE to predict spinel vs inverse spinel structures!