What is Isolobal Species ?

What are Isolobal Species? Discuss their Extension, Significance, and Examples.

Isolobal means similar to lobes (from Greek iso- meaning same, and lobos meaning lobe).

Isolobal species is also known as the isolobal analogy which helps to draw parallels between the structures and bonding of organic and inorganic molecular fragments. In simpler terms, isolobal fragments are "electronically equivalent" in their frontier orbitals, allowing them to be conceptually interchanged in molecules while retaining similar bonding characteristics. The isolobal relationship is often represented by a double-headed arrow with a looped line in the middle. Isolobal species are somewhat similar to isoelectronic species as they possess the same number of valence electrons and structure.

Isolobal analogy concept was proposed by Hoffmann. Two molecular fragments are considered to be an isolobal if they have:

1. Same number of frontier orbitals
2. Frontier orbitals with similar symmetry
3. Frontier orbitals with approximately the same energy
4. Same number of electrons in their frontier orbitals

Isolobal Fragments of Main Group Elements

For main group elements, the number of frontier orbitals and the number of electrons in them can often be determined by considering how many electrons are needed to achieve a stable octet configuration (octet rule).

For example: A methyl radical, (CH₃*), has 7 valence electrons (4 from carbon, 3 from hydrogen). To achieve an octet, it needs one more electron, residing in a single frontier orbital.
An amino radical, (NH₂*), also has 7 valence electrons (5 from nitrogen, 2 from hydrogen) and a single frontier orbital with one electron.
A hydroxyl radical, (OH*), similarly has 7 valence electrons (6 from oxygen, 1 from hydrogen) and a single frontier orbital with one electron. Thus,

CH₃ NH₂ OH F Cl

Isolobal Fragments of Transition Elements

For transition metals, the 18-electron rule often serves as a guideline for stability. To find isolobal fragments:
Start with a stable 18-electron complex, such as ML_n (where M is a transition metal and L is a two-electron donating ligand like CO, NH₃ etc.).
Remove one ligand (L), which formally leaves the metal center with one fewer electron and a vacant coordination site (a frontier orbital).
To maintain charge neutrality in the isolobal fragment, the metal's electron count is adjusted.
For example, if we remove a neutral ligand from a neutral complex, the metal center in the resulting fragment formally gains one electron.

Compare the resulting transition metal fragment with main group fragments based on the number of frontier orbitals and electrons.

For example, a metal complex with electron count of 17 electrons, such as Mn(CO)₅, there is one frontier orbital with one electron. This implies that a 17 VE carbonyl fragment is isolobal to a 7 VE organic fragment such as CH₃.

Similarly, For a 16 VE fragment such as Fe(CO)₄ there are two frontier orbitals with one electron in each of them, and is isolobal to a 6 VE fragment such as CH₂.
For a 15 VE fragment such as Co(CO)₃ there are three frontier orbitals with overall three valence electrons and is isolobal to a 5 VE fragment such as CH.

Examples of Isolobal Species

CH₃ and Mn(CO)₅

CH₃ has one singly occupied sp³ hybrid orbital.
Mn(CO)₅ has 17 valence electrons (7 from Mn + 5 × 2 from CO) and one singly occupied d orbital that can participate in bonding.
Thus, CH₃ Mn(CO)₅∙

CH₂ and Fe(CO)₄

CH₄ has 8 valence electrons.
Removing two hydrogen atoms to form CH₂ leaves 6 valence electrons and two frontier orbitals (often considered as two sp³ hybrid orbitals).
Fe(CO)₅ is an 18-electron complex.
Removing one CO ligand gives Fe(CO)₄, which has 16 valence electrons (8 from Fe + 4 × 2 from CO) and two frontier orbitals.
Thus, CH₂ Fe(CO)₄.

CpCo(CO)₂ and CpFe(CO)₂⁺

In CpCo(CO)₂, Cobalt (Co) has 9 valence electrons, cyclopentadienyl (Cp) typically donates 5 electrons, and each carbonyl (CO) donates 2 electrons,
So, number of electrons = 9 + 5 + 2(2) = 18 electrons.
If we consider the CpCo(CO)₂ fragment as having one "dangling" orbital after potentially forming a bond, we can analyze its frontier orbitals.
In CpFe(CO)₂⁺, Iron (Fe) has 8 valence electrons, Cp donates 5, and each CO donates 2,
So, total number of electrons = 8 + 5 + 2(2) = 17 electrons.
The +1 charge reduces the electron count to 16.

Similar to the Co complex, this fragment also has frontier orbitals available for bonding. While the overall electron counts of the complexes are different, the isolobal analogy focuses on the frontier orbitals of the fragments that would be involved in forming a bond. In this case, both fragments can be considered isolobal in certain bonding scenarios.

BH and Fe(CO)₃

BH₃ has 6 valence electrons.
Removing two hydrogen atoms gives BH with 4 valence electrons and two frontier orbitals.
Fe(CO)₅ is an 18-electron complex.
Removing two CO ligands gives Fe(CO)₃ with 14 valence electrons (8 from Fe + 3 × 2 from CO) and two frontier orbitals.
Thus, BH Fe(CO)₃.

Extensions of the Isolobal Analogy

The concept of isolobal fragments can be extended beyond the examples given so far to include charged species, a variety of ligands other than CO, and organometallic fragments based on structures other than octahedral. Some of the ways of extending the isolobal parallels can be summarized as follows:

1. The isolobal definition may be extended to isoelectronic fragments having the same coordination number. For example,
Mn(CO)₅ Re(CO)₅ Fe(CO)₅⁺ Cr(CO)₅⁻ CH₃

2. Gain or loss of electrons from two isolobal fragments yields isolobal fragments. For example
Mn(CO)₅ CH₃

Cr(CO)₅ Mo(CO)₅ W(CO)₅ CH₃⁺

Note that all the examples shown above are one ligand short of the parent complex. Fe(CO)₅ is isolobal with CH₃^-, for example, because both have filled electron shells and both are one vertex short of the parent polyhedron. By contrast, Fe(CO)₅ and CH₄ are not isolobal. Both have filled electron shells (18 and 8 electrons, respectively), but CH₄ has all vertices of the tetrahedron occupied, whereas Fe(CO)₅ has an empty vertex in the octahedron.

3. Other 2-electron donors are treated similarly to CO
Mn(CO)₅ Mn(PR₃)₅ [MnCl₅]⁵⁻ Mn(NCR)₅ CH₃

4. η⁵-C₅H₅ and η⁶-C₆H₆ are considered to occupy three coordination sites and to be 6-electron donors
η⁵-C₅H₅Fe(CO)₂ and η⁶-C₆H₆Mn(CO)₂ [Fe(CO)₅]⁺ Mn(CO)₅

η⁵-C₅H₅Mn(CO)₂ and η⁶-C₆H₆Cr(CO)₂ [Mn(CO)₅]⁺ Cr(CO)₅

5. Octahedral fragments of formula ML_n, (where M has a d^x configuration) are isolobal with square-planar fragments of formula ML_{n - 2} (where M has a d^{x + 2} configuration and L = 2 -electron donor).

Octahedral Fragments		Square Fragments
MLn		ML(n-1)
Cr(CO)5		[PtCl3]−
d6		d8
Fe(CO)4		Pt(PR3)2
d8		d10

The fifth of extensions of the isolobal analogy is less obvious than the others.

Significance of the Isolobal Analogy

Isolobal analogy is particularly useful to understand the structures and bonding in complex carbonyl and organometallic compounds by relating them to simpler molecules.

It can be used to predict the stability, reactivity, and other properties of organometallic compounds by drawing parallels with known organic and inorganic compounds.

Isolobal analogy allows to predict the existence and structures of new organometallic compounds by analogy to known organic or inorganic compounds. If a stable organic molecule exists with a certain framework, replacing a fragment with an isolobal organometallic fragment might lead to a stable compound.

Similar isolobal fragments often exhibit similar reactivity patterns.

CSIR-UGC: NET/JRF Chemical Sciences: September 2022

Identify the series showing isolobal analogy.

A. CH₃, [Fe(CO)₅]⁺
B. CH₅⁺, [Cr(CO)₅]^-
C. CH₅⁺, Ni(CO)₃
D. CH⁺, CpCo

1. A and B only
2. A, C, and D only
3. B and C only
4. A and D only

Answer: 2. A, C, and D only

CSIR-UGC: NET/JRF Chemical Sciences: June 2016

CpM fragment isolobal with BH fragment is

A. CpGe
B. CpMn
C. CpRu
D. CpCo

Answer: D. CpCo

CSIR-UGC: NET/JRF Chemical Sciences: December 2016

According to isolobal analogy, the right set of fragments that might replace Co(CO)₃ in [Co₄(CO)₁₂] is

A. CH, BH and Mn(CO)₅
B. P, CH, and Ni(n⁵-C₅H₅)
C. Fe(CO)₄, CH₂ and SiCH₃
D. BH, SiCH₃ and P

Answer: B. P, CH, and Ni(n⁵-C₅H₅)

CSIR-UGC: NET/JRF Chemical Sciences: June 2014

Amongst the following, which one is not an isolobal pair

A. Mn(CO)₅, CH₃
B. Fe(CO)₄, O
C. Co(CO)₃, R₂Si
D. Mn(CO)₅, RS

Answer: C. Co(CO)₃, R₂Si

CSIR-UGC: NET/JRF Chemical Sciences: December 2019

The organic species isolobal to [Fe(CO)₂(PPh₃)]^– is

A.CH₂⁺
B. CH^–
C. CH₃
D. CH

Answer: D. CH