Even though the M_r for Fe(CO)₅ is quite high (195.9), the fact that the melting point is quite low suggests that the molecule is non-polar.  [1]

(The attractive forces between the non-polar Fe(CO)₅ molecules are therefore weak London (dispersion forces) so little energy is required to overcome these attractive forces resulting in a low melting point. The boiling point is above room temperature as the molecules do have considerable mass/electrons which does increase the London (dispersion) forces.

Underlying chemistry concepts can be found in 4.4 Intermolecular forces.)

There are five bonding pairs and no non-bonding pairs so the shape is the regular shape for five electron domains - trigonal bipyramid. [1]

(Since Fe(CO)₅ is non-polar it must have a symmetrical shape with no non-bonding pairs of electrons around the central iron atom (if there were it would be octahedral and polar). Although each CO ligand is polar, when the five ligands are arranged in a trigonal bipyramid shape the resultant dipole is zero.

Fe(CO)₅ trigonal bipyramid

Underlying chemistry concepts can be found in 14.1 Further aspects of covalent bonding.)

  [1]

(Carbon monoxide contains a coordinate bond as the two electrons in one of the triple bond pairs originate from the oxygen atom.

Underlying chemistry concepts can be found in 4.2 Covalent bonding.)

The formal charge on the C atom = 4 - 2 - ( ½ x 6) = – 1
and the formal charge on the O atom = 6 -2 - ( ½ x 6) = + 1  [1]

Since the negative formal charge is on the carbon atom it is this non-bonding pair that forms a coordinate bond to the iron atom. [1]

(Underlying chemistry concepts can be found in 14.1 Further aspects of covalent bonding.)

The oxidation state of Fe goes from 0 in Fe(CO)₅ to +2 in Fe(CO)₄Cl₂
The oxidation state of Cl goes from 0 in Cl₂ to – 1 in Fe(CO)₄Cl₂
Therefore this is a redox reaction in which the iron is oxidized from 0 to +2 and the chlorine is reduced from 0 to – 1. [1]

(Underlying chemistry concepts can be found in 9.1 Oxidation & reduction.)

There are six ligands and no non-bonding pairs of electrons around the central iron ion so the geometric shape of the complex will be octahedral. [1]
However there are two possibilities as it could exist as a cis- or trans- isomer. [1]

(Underlying chemistry concepts can be found in 14.1 Further aspects of covalent bonding and 20.3 Stereoisomerism.)

From the two equations Fe(CO)₅(g) → Fe(s) + 5CO(g) and xCO(g) → CNT(s) + ½xCO­₂(g), 1 mol of Fe(CO)₅(g) produces 2.5 mol of CNT. [1]

Assuming molar quantities
Mass of reactants = 55.85 + 5 x (12.01 + 16.00) = 195.90 g
Mass of desired product = 2.5 x 12.01 = 30.025 g
Atom economy = (30.025/195.90) x 100 = 15.3%  [1]

(Obviously if the iron and/or the carbon dioxide can be recycled then the atom economy would be much higher.

Underlying chemistry concepts can be found in 1.3 Reacting masses and volumes.)
Strictly speaking this sub-topic talks about the importance of percentage yield in industrial processes but atom economy does appear in Option A : Materials (A.5 Polymers) and Option B : Biochemistry (B.6 Biochemistry & the environment) and Green chemistry is mentioned in Option D : Medicinal chemistry (D6 - Environmental impact of some medications).