Metal-Ligand Bonding and Inorganic Reaction Mechanisms

Question 1

What is hapticity (η)?

Answer 1

The number of contiguous atoms of a ligand attached to a metal

Question 2

What is the difference between η1-O2 and η2-O2?

Answer 2

For η1 the metal atom is bound only to 1 oxygen atom whereas in η2 the metal is bound to both atoms

Question 3

What is denticity (κ)?

Answer 3

The number of donor groups in a given ligand that bind to the central metal atom (from latin meaning tooth)

Question 4

What is μ?

Answer 4

The number of metal atoms a ligand is bound to

Question 5

What is the equation for oxidation state?

Answer 5

Oxidation state = charge on complex - sum of the charges of all the ligands

Question 6

How can you calculate the charge on a ligand?

Answer 6

Ask yourself how many H are needed to make a neutral molecule. (Except NO (linear) which is +1)

Question 7

By convention, how are formal charges written and why?

Answer 7

Written as Roman Numerals, in reality atoms only have ±1 electron - the formal charge is not the actual charge distribution

Question 8

What is the equation for d-electron count?

Answer 8

d-electron count = group number - oxidation state

Question 9

What is the equation for total valence electron count (TVEC)?

Answer 9

TVEC = d-electron count + electrons donated by the ligands + number of M-M bonds

Question 10

What are the 3 facts that determine if a ligand bonds to a metal and with how much energy in terms of orbitals?

Answer 10

a) Orbitals must have appropriate symmetry
b) Orbitals must overlap
c) Orbitals must be of similar energy

Question 11

For an anti-bonding orbital, will it look more similar to the highest energy AO or lowest energy AO?

Answer 11

The highest energy AO as the antibonding orbital is high in energy. The same is true for the lowest energy AO and the bonding orbital

Question 12

What is an indication that a molecule isnt stable in an MO diagram?

Answer 12

If electrons occupy an antibonding orbital

Question 13

If there are 9 AO how many MO will there be?

Answer 13

Also 9.
n. of AOs = n. of MOs

Question 14

What are the 3 types of orbitals in an MO diagram?

Answer 14

1) Bonding
2) Non-bonding
3) Anti-bonding

Question 15

What are the 3 different types of ligand?

Answer 15

1) σ-donor
2) σ-donor, π-acceptor
3) σ-donor, π-donor

Question 16

What do σ-donor ligands have? List some examples

Answer 16

A ‘lone pair’ of electrons to donate to the metal
- H, CH3, H2O, NH3, NR2(bent), R

Question 17

What do π-acceptor ligands have? List some examples

Answer 17

A ‘lone pair’ of electrons and an empty orbital to accept electron density from the metal
- CO, CN, NO, H2, Alkenes, N2, O2, PR3, BR2

Question 18

What do π-donator ligands have? List some examples

Answer 18

Multiple ‘lone pairs’ to donate to the metal
- Halides, O, OR, S, SR, N, NR2(linear), NR2(bent & linear), P, delocalised rings

Question 19

In an MO diagram for a metal and its ligands, which orbitals determine bonding?

Answer 19

The frontier orbitals - the HOMO and LUMO

Question 20

Synergic bonding occurs during σ-donor, π-acceptor ligand bonding. Explain what synergic bonding is and what happens to electron density on the metal centre during this ligand bonding.

Answer 20

Synergic bonding - The bond is self strengthening (both effects reinforce each other)
σ-donor interaction increases electron density on the metal centre and away from the ligand
π-acceptor interaction decreases electron density on the metal and increases electron density on the ligand

Question 21

How do π-acceptor ligands stabilise low oxidation state metals?

Answer 21

They relieve high electron density around the metal centre

Question 22

Experiments show decreasing the oxidation state of a metal results in a decrease in the bond strength within a π-acceptor ligand (e.g. C-O bond in CO). Why?

Answer 22

π-acceptor interaction increases as electron density is accepted by the C atom weakening the C-O bond. (Essentially resulting in a change in bonding from M-C≡O to M=C=O)

Question 23

Experiments show decreasing the number of ligands around a metal decreases the bond strength within a ligand for any remaining π-acceptor ligands. Why?

Answer 23

Decreasing the number of ligands increases the electron density around the metal centre which is then distributed to the rest of the π-acceptor ligands. This increases the π-acceptor interaction which lowers and bonding within the ligand

Question 24

Experiments show that the bond strength of C-O within a CO ligand changes when using different π-acceptor ligands for a given metal. What does this tell us about the other ligands being used?

Answer 24

If the C-O bond strength is decreasing then more electron density must be around the C and so there must be a stronger π-acceptor interaction. This suggests that the other π-acceptor ligand must be a weaker π-acceptor. The opposite is also true, if the C-O bond strength increases then it is becoming a worse π-acceptor and the other ligand must be a better acceptor

Question 25

For CO, what does increasing the number of metal centres do to the C-O bond strength?

Answer 25

Increasing the metal centres increases the electron density and increases the π-acceptor interaction and therefore decreases the bond strength

Question 26

What two other ligands bond similarly to the π-acceptor ligand of CO?

Answer 26

CN- and NO+

Question 27

In terms of orbital size, why is the CO ligand more reactive than the N2 ligand?

Answer 27

C has a larger orbital resulting in greater overlap and bond strength than M-N. As a π-acceptor, the C-O bond weakens more than the N-N bond so it is more reactive

Question 28

What are the three possible ‘forms’ of the O2 molecule binding to a metal centre?

Answer 28

• Neutral M - O2
• Superoxide M(+) - O2(-)
• Peroxide M(2+) - O2(2-)

Question 29

What does populating the anti-bonding orbitals in O2 do to the O-O bond?

Answer 29

It weakens the O-O bond. Neutral O2 has a stronger bond than superoxide which is stronger than peroxide

Question 30

What happens if the anti-bonding LUMO for O2 is completely occupied?

Answer 30

The bond order = 0 - the O-O is completely broken

Question 31

What are the two ways in which covalent bonds are broken? (In relation to MO theory)

Answer 31

1) Increase electron density in anti-bonding orbitals
2) Decrease electron density in bonding orbitals

Question 32

What are the two terminal coordination modes that NO can bind by?

Answer 32

Bent (double bond) and Linear (triple bond)

Question 33

How many electrons does linear NO donate and what is its formal charge?

Answer 33

3e NO+

Question 34

How many electrons does bent NO donate and what is its formal charge?

Answer 34

1e NO-

Question 35

How do we calculate what terminal mode (bent or linear) NO is in?

Answer 35

1) Remove NO (neutral) from the molecule and calculate electron count and oxidation number of fragment
2) Add 1e or 3e to get to 18e (or as close as possible)
3) Determine the metal oxidation state using either NO+ or NO-

Question 36

How does oxidative addition occur?

Answer 36

Sufficient electron density is transferred from the metal centre to the σ* orbital of H2 resulting in bond rupture and formation of a dihydride complex. (increasing oxidation state)

Question 37

What do NMR spectra show occurs to alkene complexes?

Answer 37

At high temperatures the spectra have low resolution and at low temperatures the spectra have high resolution - suggesting the alkenes are spinning

Question 38

What increases the activation energy of alkene rotation?

Answer 38

The π-bond changes during spinning so the stronger the π-acceptor interaction the higher the activation energy for rotation

Question 39

For a π-donor interaction what is needed?

Answer 39

A full ligand orbitals AND an empty metal orbitals

Question 40

What is interesting about the oxide (O2 (-)) ligand?

Answer 40

It can exhibit double or triple bond character - donating either 4e or 6e

Question 41

How many electrons can an amido (NR2 (-)) donate?

Answer 41

2e or 4e

Question 42

How many electrons can an imido (NR2-) donate?

Answer 42

4e or 6e

Question 43

How do we electron count for with π-donor interactions?

Answer 43

1) Calculate the charge on the ligands for the Oxidation state
2) Group number - oxidation for d-electron count
3) d-electron + electrons donated which could be a range depending on amount of π-donation

Question 44

How many electrons does N(3-) donate?

Answer 44

6e

Question 45

What happens to Δoct for π-acceptor and π-donor ligands compared to just σ-donor ligands?

Answer 45

For π-acceptor ligands, the t2g orbital decreases in energy from the eg orbital resulting in an increase in Δoct
For π-donor ligands, the t2g orbital increases in energy towards the eg orbital resulting in a decrease in Δoct

Question 46

What is the spectrochemical series?

Answer 46

A list of ligands in order of increasing field strength
π-acceptor > σ-donor > π-donor
The larger Δoct the stronger the field strength

Question 47

For π-donor ligands the t2g orbital becomes π*. Why does this mean that complexes with π-donor ligands are less likely to follow the 18e rule?

Answer 47

It is less energetically favourable to fill the anti-bonding orbitals

Question 48

Are high spin or low spin complexes inert?

Answer 48

Low spin complexes are inert, high spin complexes are labile as t2g and eg are similar in energy and so an electron can be moved

Question 49

What are the two inorganic reaction mechanisms that we study?

Answer 49

1) Ligand substitution
2) Electron transfer (redox)

Question 50

Which complexes are labile?

Answer 50

1st row and d10 complexes

Question 51

What is the difference between a dissociative and associative ligand substitution? And what is the RDS for each?

Answer 51

Dissociative - loss of a ligand. RDS is breaking of M-L bond
Associative - gain of a ling. RDS is forming M-L bond

Question 52

What are ΔS‡ and ΔV‡ and why if both of theses are negative indicate that an associative mechanism has occurred?

Answer 52

ΔS‡ - entropy difference between initial state and transition state
ΔV‡ - volume difference between initial state and transition state
If both a negative this suggests lower disorder and smaller volume in the transition state

Question 53

For square planar molecules during ligand substitution stereochemistry is usually preserved. Why is it sometimes not preserved?

Answer 53

If the 5-coordination transition state complex is long lived then Berry pseudorotation can occur

Question 54

What are the 4 thing that effect the rate of ligand substitution?

Answer 54

1) The entering group
2) The leaving group
3) The nature of the other ligands in the complex
4) The metal centre

Question 54

What is the trans-effect?

Answer 54

A kinetic phenomenon that describes the influence on a non-labile group on the rate of substitution of a ligand trans to it.
π-acceptor > π-donor > σ-donor

Question 55

For a “soft” metal like Pt is the rate of substitution by an entering group faster for “soft” or “hard” nucleophiles?

Answer 55

The rate is greater for “soft” nucleophiles

Question 56

For a “soft” metal like Pt is the rate of substitution by a leaving group faster for “soft” or “hard” nucleophiles?

Answer 56

The rate is greater for “hard” nucleophiles

Question 57

What is ΔG‡?

Answer 57

The free energy of activation - the difference between the reactant ground state and the first transition state

Question 58

What are the two ways to decrease ΔG‡?

Answer 58

1) Destabilise the ground state by weakening the bond trans- to the ligand leaving
2) Lower the energy of the transition state with a ligand with π-acceptor character to accept electron density from the nucleophile

Question 59

As you go down a group are the M-L bonds in a complex more or less strong

Answer 59

More strong as orbitals are larger and have better overlap

Question 60

For octahedral ligand substitutions which of the 3 mechanisms is like SN1, SN2 and rare?

Answer 60

Associative - must go via a 7 coordinate intermediate and is rare
Dissociative - SN1
Interchange - SN2 and most common (simultaneous bond breaking and making)

Question 61

What suggests that there is a dissociate RDS in octahedral ligand substitution reactions?

Answer 61

1) Varying the entering group makes little difference to the rate
2) Plotting bond strength vs rate gives a linear free energy relationship
3) Large spectator ligands means that the transition state is preferred and the rate increases
4) If the mechanism was associative then 20e intermediate complexes would be formed which is unfavourable compared to 16e complexes for the dissociative mechanism

Question 62

What are the two electron transfer mechanisms that we consider?

Answer 62

• Outer sphere mechanisms
• Inner sphere mechanisms

Question 63

What occurs in outer sphere mechanisms?

Answer 63

Electrons are transferred between complexes without substitution - no bonds a formed or broken

Question 64

What occurs in inner sphere mechanisms?

Answer 64

Electrons are transferred between complexes via a bridging ligand - bonds are broken and formed

Question 65

What are the 3 steps in outer sphere mechanisms?

Answer 65

1) Formation of precursor complex
2) Activation/reorganisation of precursor complex. Electron transfer. Relaxation of successor complex
3) Dissociation of successor complex

Question 66

Why do the M-L bonds change length?

Answer 66

So that the electron can jump between orbitals of similar energy

Question 67

Why must the M-L bond change first?

Answer 67

The change in coordination number of the complex will cause the bonds to change lengths and release heat - we need to put in energy to ensure the conservation of energy

Question 68

Does a large change in bond length mean the electron transfer is fast or slow, and is it faster for eg or t2g?

Answer 68

Small bond length change is faster
eg –> eg (σ) is a large bond length change and therefore a slow electron transfer (+poor orbital overlap)
t2g –> t2g (π/π/nb) is a small bond length change and therefore a fast electron transfer

Question 69

Why do 2nd and 3rd row complexes have faster outer sphere electron transfers than 1st row?

Answer 69

Their orbitals are bigger and have larger orbital overlaps

Question 70

During inner sphere electron transfer a bridging ligand must be formed, what must happen in an octahedral complex for this to occur?

Answer 70

Ligand dissociation must occur to allow a bridging ligand to bond

Question 71

How can we prove that when a ligand is transferred from one complex to another in an inner sphere transfer, that it DIRECTLY comes from the other complex and not from solution?

Answer 71

We can isotopically label that ligand before the transfer and find the same ligand on the other complex after the electron transfer

Question 72

Is ligand transfer a requirement for an inner sphere mechanism?

Answer 72

NO - It depends on the relevant bond strengths of both complexes and all their ligands

Question 73

What factors affect the rate of inner sphere electron transfer mechanisms?

Answer 73

• Electron transfer is usually the RDS but the formation of the bridging complex (or dissociation of the complex) could be the RDS
• The bridging ligand
• Which orbitals are involved

Question 74

Why is inner sphere electron transfer so fast for eg orbitals?

Answer 74

There is good orbital overlap of the eg orbitals in the molecular bonding orbital

Question 75

What are two factors that affect how good a bridging ligand is for inner sphere electron transfer?

Answer 75

1) The size of R groups - larger R groups cause steric hinderance
2) The ligand might be able to mediate the electron transfer which circumvents the need for reorganisation of complexes in outer sphere transfer

Question 76

How do we distinguish if electron transfer is outer or inner sphere?

Answer 76

• Is there a vacant coordination site?
• Is there a labile reactant?
• Is there a potential bridging ligand?
• Has a ligand been transferred in the reaction?
• Are there large differences in rate on addition or substitution of a bridging ligand?

Question 77

How can we tell if an electron transfer is outer or inner when using the rates for N3- and NCS-?

Answer 77

If kN3-/kNCS- ~ 1 then it is outer sphere
If kN3-/kNCS-&raquo_space; 1 then it is inner sphere