Week 10 Crystal Field Theory Workbook - Monash S2 2024 PDF

Summary

This workbook introduces crystal field theory and covers different types of structural isomerism in coordination complexes like geometric, optical, and linkage isomers. It gives an overview of the topic, with explanations, diagrams, and examples. It's intended for a chemistry II course.

Full Transcript

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Week 10: Crystal Field Theory - Workbook

Site: Monash Moodle1 Printed by: Kaltham Alzaabi
Unit: CHM1022 - Chemistry II - S2 2024 Date: Sunday, 22 September 2024, 12:32 PM
Book: Week 10: Crystal Field Theory - Workbook

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Table of contents

1. Pre-workshop material
1.1. Isomers in coordination chemistry
1.2. Colour and magnetism
1.3. Crystal field theory
1.4. Videos

2. Summary

3. Preparation quiz

4. Online lectures

5. Workshops

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1. Pre-workshop material

This week we are going to discover different types of isomers that coordination complexes can adopt. Isomers are complexes that have
the same chemical formula but different structural or spacial arrangements. With coordination complexes this is also true, except that
due to the variety of ligands and coordination geometries available various sub-categories of isomer types are available to one metal
coordination complex.

We will also introduce Crystal Field Theory. This will be used to help explain why transition metal complexes are coloured and why some
coordination complexes are attracted to a magnetic field. Overall we will explain the ultimate importance of unpaired electrons and their
ability to move between d-orbitals of different energies!

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1.1. Isomers in coordination chemistry

Please read pages 766-770 (Isomerism in transition metal complexes) and pages 779-784 (Bonding in Transition metal

complexes) of Chemistry, Blackman et al (4th ed.)

Isomerism in Coordination Compounds

In the early history of coordination chemistry, the existence of pairs of compounds with the same formula yet different properties
proved very perplexing to inorganic chemists. Werner was studying Co and Pt complexes and noticed that some had that some had
different colours, yet analysed for the same formula!

He was among the first to realise that the different properties represented different structural arrangements (isomers).

In Figure 1, the NO2- ligand is bound to the central Co atom in two different ways, one through the N atom and one through one of the O
atoms.

This approach also correctly enables us to predict that there are two possible forms of [CoCl2(NH3)4]Cl. One of these has the two Cl
ligands next to each other, the other has them opposite each other (Figure 2)

Figure 1: Two isomers of [Co(NH3)5(NO2)]2+. The left hand structure has the oxygen bonded to the Co and the right hand structure has
the nitrogen bonded to the Co.

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Approach correctly predicts there would be two forms of
“CoCl3∙4NH3”

The formula would be written
[CoCl2(NH3)4]Cl

One form has the two chlorides next to each other.

The other has them opposite each other.

Figure 2: The two different structural isomers
of [CoCl2(NH3)4]+

Alfred Werner - Werner's Insights

There are two main types of isomerism in coordination compounds. In structural isomers there are different bonds between the central
metal atom and the ligands. In stereoisomerism the bonds between the metal and the ligands are the same but the ligands are
arranged differently in space around the metal ion. Figure 3 is a summary of the types of isomers you will see in inorganic molecules.

Isomerism in Coordination Compounds

Figure 3. A summary of the types of isomers in inorganic complexes. Note the similarities with isomerism in organic compounds

Isomerism: Structural Isomers

Linkage isomerism – where a single ligand has two or more donor atoms and can attach in more than one way (Figure 4).

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Pentaamminethiocyanato-κS-cobalt(III)
[Co(NH3)5(SCN)]2+
vs
Pentaamminethiocyanato-κN-cobalt(III)
[Co(NH3)5(NCS)]2+

Figure 4. Example of ligands that can form linkage isomers

Hydration and Ionisation isomers

Exchange of ligands in coordination complex with counter-ions and water molecules.

Hydration isomers involve water swapping with a ligand

[CrCl2(OH2)4]Cl▪2H2O [CrCl(OH2)5]Cl2▪H2O

Ionisation isomers involve exchange of anionic ligands with counter anions

[PtCl2(NH3)4]I2 [PtI2(NH3)4]Cl2

Coordination isomerism

Can occur when both a complex cation and anion are present.

This allows for multiple combinations of ligands coordinated to the two metal centres.

[Co(bpy)3][Fe(CN)6] [Co(bpy)2(CN)2][Fe(bpy)(CN)4] [Fe(bpy)3][Co(CN)6]

Isomerism: Stereoisomers

In stereoisomers we see parallels with isomerism in organic chemistry for example cis/trans and optical isomerism. Remember
stereoisomers are molecules with the same number of ligands bonded to the metal, but in different arrangements in space.

Geometric Isomers

The geometric isomers you will need to know are the cis/trans isomers and the fac/mer isomers.

Cis-isomers are when the identical ligands are adjacent to each other. Trans-isomers are when they are on opposite sites of the metal
centre (Figure 6).

Example (Figure 5):
Cisplatin in a highly effective and widely used anticancer drug with formula cis-[PtCl2(NH3)2]. Especially effective in ovarian and
testicular cancers. Interestingly trans-[PtCl2(NH3)2] is not active and is toxic!!

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Robbie Gray - cancer survivor

Figure 5: The cis- and trans-isomers of platin [PtCl2(NH3)2] complex.

Figure 6: The cis- and trans-isomers of square planar and octahedral complexes

Fac/mer isomerism can occur for octahedral complexes with three ligands of one type and three of another. Facial (fac) isomers are
when the identical ligands are all adjacent to each other - i.e. they occupy a face of the octahedron defined by the donor atoms around
the metal. Meridional (mer) isomers are when the identical ligands lie around a meridian of the complex - i.e. two ligands are on
opposite sides of the complex, with the third lying adjacent to the other two (Figure 7).

Figure 7: The fac- and mer-isomers of an octahedral complex

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Optical isomers

Occur most commonly when there is more than one bidentate ligand in the complex. Just as in organic chemistry, optical isomers are
non-superimposable mirror images of each other. Enantiomers are also stereo isomers i.e. mirror images that are non-
superimposable.

Figure 8: Two examples of optical isomers: First is cis-[CoCl2(en)2]+ and second is cis-[Co(en)3]3+ (Blackman's Figure 16:11)

Explore the 3D representation of the molecular structure of [Ru(en]3)2+ enantiomers illustrated in this ChemTube 3D page (click the
link).

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1.2. Colour and magnetism

Colours and Magnetism

Colour - Many transition metal compounds are coloured. Electrons in partially filled d-orbitals can absorb visible light and move to d-
orbitals with slightly higher energy. There will be more on this later.

(Sc3+, Ti4+ and Zn2+ are exceptions -they have filled or empty d-subshells)

Figure 8. Examples of coloured and non-coloured complexes

Magnetism - typically transition metals have a partially filled set of d-orbitals and some of the d-electrons may be unpaired. These
unpaired electrons give rise to the complex being paramagnetic. Paramagnetic compounds are attracted to a magnetic field. These
unpaired electrons can be randomly aligned. If they are aligned in the same direction then we observe ferromagnetism. If all electrons
are paired this gives rise to diamagnetism. Diamagnetic compounds are repelled by a magnetic field.

Diamagnetic - all electron spins paired; Paramagnetic - unpaired spins. Magnetic fields are randomly arranged, unless placed in an external

no net magnetic moment. magnetic field - Ferromagnetic

Figure 9: An example of a diamagnetic and paramagnetic molecule's electrons

Group 1 and 2 ionic compounds (eg Na+, Ca2+) are colourless and diamagnetic whereas many coordination complexes are coloured
(Figure 10) and exhibit magnetic properties. But, how is this possible? Aren’t the 3d orbitals equal in energy?

We need a model of bonding that explains colour and magnetism.

Transition Metals and Colour

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Figure 10: A list of various colours observed from numerous complexes.

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1.3. Crystal field theory

Crystal Field Theory

Valence Bond Theory

You were introduced to valence bond theory in the organic section, where hybrid orbitals are formed to explain the geometry of the
molecule's bonds (Figure 11).

Complex formation is explained by donation of electron pair(s) (by a Lewis Base) to a metal ion (Lewis acid) to form a coordination
bond. Hybrid orbitals of equal energy provide no explanation for the colour and magnetic properties of transition metal complexes. So
valence bond theory fails. In this regard we use a more sophisticated model called Crystal Field Theory.

Figure 11: Possible hybrid orbitals for geometrical shapes found in complexes.

New Theory Needed: Crystal Field (CF) Theory

This model explains stability, colour and magnetism but not the nature of metal-ligand bonding. It describes how the energies of the d-
orbitals on the metal ion are affected as the ligands approach.

Important Assumption

Complexes result from electrostatic attractions between metal cation and negative charges or lone pair of electrons on ligands. (i.e.
they are not covalent in character)

Important Question: What happens to the energy of the metal d-orbitals when 6 ligands approach?

Consider that the ligands (balls of negative charge) can approach the metal centre (uniform positive charge) in two ways:

(i) Directly along the x, y, z, axes

or

(ii) Between the axes

If we consider the 6 point charges are directed at the metal along the three axes, we will observe greater ligand – d electron
repulsion from those electrons on the x-, y- and z-axes (i.e. in dx2-y2 and dz2 orbitals), rather than those between axes (dxy, dyz, dxz) - see
Figure 12. In other words, higher energy is required for some d-orbitals as the complex forms bonds with the ligands. This is due to the
two sets of negatively charged electrons (1 set from the lone pair on the ligand and the other from the d-orbitals) overcoming their
repulsion of each other to form that complex bond.

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Figure 12. The change in energy of the d-orbitals when ligands approach along the x-, y- and z-axes, as for an octahedral complex

Explore the 3D representation of the metal d-orbitals in an octahedral crystal field illustrated in this ChemTube 3D page (click the link).

Steps to Complex Formation

The five d-orbitals increase in energy relative to free Mn+ ion due to greater ligand - d-electrons repulsion. However, they are not equally
affected (Figure 13).

Figure 13: The shape of all 5 d-orbitals and how their energy levels are affected by octahedral ligands.

Direct head-to-head repulsion leads to a higher energy (more unstable) situation for dz2 or dx2-y2 orbitals – collectively referred to as
the eg orbitals.

Tangential repulsion (more side-on) leads to a relatively lower energy situation for dxy, dxz and dyz orbitals – collectively referred to as
the t2g orbitals.

The energy difference between eg and t2g is Δoct (or Δo) - Figure 14.

Figure 14: The energy levels of the 5 d-orbitals after an octahedral complex is formed

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1.4. Videos

Electron Orbitals

This video is designed to help you visualise the s-, p- and d-orbitals. Notice how the five d-orbitals fit together in 3 dimensions.

Electron Orbitals - s,p & d

Crystal Field Theory

This video demonstrates Crystal Field Theory. In particular, the splitting of d orbitals that occurs when transition metal ions are placed
in an octahedral or tetrahedral field.

Crystal Field Theory | Chemistry Animation Energy Video | L…
L…

Reference: Classteacher Learning Systems

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2. Summary

This week you have learnt that coordination complexes can have different types of structural isomerism which can be sub-categorised
into different groups including: structural – coordination and linkage or stereioisomers – geometric and optical. You have also learnt
that one coordination complex can have more than one type of isomer dependent on the ligands attached to the metal center.

We have also learnt that the five d-orbitals are not degenerate and introduced Crystal Field Theory to help explain the bonding seen in
transition metal coordination complexes. We have looked at Crystal Field Theory for octahedral, tetrahedral, square planar and square
pyramidal geometries and are able to predict and draw the representative Crystal Field splitting diagrams for each geometry along with
an explanation of why they are all different.

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