In chemistry the polyhedral skeletal electron pair theory (PSEPT) provides electron counting rules useful for predicting the structures of clusters such as borane and carborane clusters. The electron counting rules were originally formulated by Kenneth Wade,[1] and were further developed by others including Michael Mingos;[2] they are sometimes known as Wade's rules or the Wade–Mingos rules.[3] The rules are based on a molecular orbital treatment of the bonding.[4][5][6][7] These rules have been extended and unified in the form of the Jemmis mno rules.[8][9]
Different rules (4n, 5n, or 6n) are invoked depending on the number of electrons per vertex.
The 4n rules are reasonably accurate in predicting the structures of clusters having about 4 electrons per vertex, as is the case for many boranes and carboranes. For such clusters, the structures are based on deltahedra, which are polyhedra in which every face is triangular. The 4n clusters are classified as closo-, nido-, arachno- or hypho-, based on whether they represent a complete (closo-) deltahedron, or a deltahedron that is missing one (nido-), two (arachno-) or three (hypho-) vertices.
However, hypho clusters are relatively uncommon due to the fact that the electron count is high enough to start to fill antibonding orbitals and destabilize the 4n structure. If the electron count is close to 5 electrons per vertex, the structure often changes to one governed by the 5n rules, which are based on 3-connected polyhedra.
As the electron count increases further, the structures of clusters with 5n electron counts become unstable, so the 6n rules can be implemented. The 6n clusters have structures that are based on rings.
A molecular orbital treatment can be used to rationalize the bonding of cluster compounds of the 4n, 5n, and 6n types.
The following polyhedra are closo polyhedra, and are the basis for the 4n rules; each of these have triangular faces.[10] The number of vertices in the cluster determines what polyhedron the structure is based on.
Number of vertices | Polyhedron |
---|---|
4 | Tetrahedron |
5 | Trigonal bipyramid |
6 | Octahedron |
7 | Pentagonal bipyramid |
8 | D2d (trigonal) dodecahedron (snub disphenoid) |
9 | Tricapped trigonal prism |
10 | Bicapped square antiprismatic molecular geometry |
11 | Edge-contracted icosahedron (octadecahedron) |
12 | Icosahedron (bicapped pentagonal antiprism) |
Using the electron count, the predicted structure can be found. n is the number of vertices in the cluster. The 4n rules are enumerated in the following table.
Electron count | Name | Predicted structure |
---|---|---|
4n − 2 | Bicapped closo | n − 2 vertex closo polyhedron with 2 capped (augmented) faces |
4n | Capped closo | n − 1 vertex closo polyhedron with 1 face capped |
4n + 2 | closo | closo polyhedron with n vertices |
4n + 4 | nido | n + 1 vertex closo polyhedron with 1 missing vertex |
4n + 6 | arachno | n + 2 vertex closo polyhedron with 2 missing vertices |
4n + 8 | hypho | n + 3 vertex closo polyhedron with 3 missing vertices |
4n + 10 | klado | n + 4 vertex closo polyhedron with 4 missing vertices |
When counting electrons for each cluster, the number of valence electrons is enumerated. For each transition metal present, 10 electrons are subtracted from the total electron count. For example, in Rh6(CO)16 the total number of electrons would be 6 × 9 + 16 × 2 − 6 × 10 = 86 – 60 = 26. Therefore, the cluster is a closo polyhedron because n = 6, with 4n + 2 = 26.
Other rules may be considered when predicting the structure of clusters:
In general, closo structures with n vertices are n-vertex polyhedra.
To predict the structure of a nido cluster, the closo cluster with n + 1 vertices is used as a starting point; if the cluster is composed of small atoms a high connectivity vertex is removed, while if the cluster is composed of large atoms a low connectivity vertex is removed.
To predict the structure of an arachno cluster, the closo polyhedron with n + 2 vertices is used as the starting point, and the n + 1 vertex nido complex is generated by following the rule above; a second vertex adjacent to the first is removed if the cluster is composed of mostly small atoms, a second vertex not adjacent to the first is removed if the cluster is composed mostly of large atoms.
Example: Pb2−
10
Example: S2+
4
Example: Os6(CO)18
Example:[11] B
5H4−
5
The rules are useful in also predicting the structure of carboranes. Example: C2B7H13
The bookkeeping for deltahedral clusters is sometimes carried out by counting skeletal electrons instead of the total number of electrons. The skeletal orbital (electron pair) and skeletal electron counts for the four types of deltahedral clusters are:
The skeletal electron counts are determined by summing the total of the following number of electrons:
As discussed previously, the 4n rule mainly deals with clusters with electron counts of 4n + k, in which approximately 4 electrons are on each vertex. As more electrons are added per vertex, the number of the electrons per vertex approaches 5. Rather than adopting structures based on deltahedra, the 5n-type clusters have structures based on a different series of polyhedra known as the 3-connected polyhedra, in which each vertex is connected to 3 other vertices. The 3-connected polyhedra are the duals of the deltahedra. The common types of 3-connected polyhedra are listed below.
Number of vertices | Type of 3-connected polyhedron |
---|---|
4 | Tetrahedron |
6 | Trigonal prism |
8 | Cube |
10 | Pentagonal prism |
12 | D2d pseudo-octahedron (dual of snub disphenoid) |
14 | Dual of triaugmented triangular prism (K5 associahedron) |
16 | Square truncated trapezohedron |
18 | Dual of edge-contracted icosahedron |
20 | Dodecahedron |
The 5n rules are as follows.
Total electron count | Predicted structure |
---|---|
5n | n-vertex 3-connected polyhedron |
5n + 1 | n – 1 vertex 3-connected polyhedron with one vertex inserted into an edge |
5n + 2 | n – 2 vertex 3-connected polyhedron with two vertices inserted into edges |
5n + k | n − k vertex 3-connected polyhedron with k vertices inserted into edges |
Example: P4
Example: P4S3
Example: P4O6
As more electrons are added to a 5n cluster, the number of electrons per vertex approaches 6. Instead of adopting structures based on 4n or 5n rules, the clusters tend to have structures governed by the 6n rules, which are based on rings. The rules for the 6n structures are as follows.
Total electron count | Predicted structure |
---|---|
6n – k | n-membered ring with k⁄2 transannular bonds |
6n – 4 | n-membered ring with 2 transannular bonds |
6n – 2 | n-membered ring with 1 transannular bond |
6n | n-membered ring |
6n + 2 | n-membered chain (n-membered ring with 1 broken bond) |
Example: S8
Hexane (C6H14)
Provided a vertex unit is isolobal with BH then it can, in principle at least, be substituted for a BH unit, even though BH and CH are not isoelectronic. The CH+ unit is isolobal, hence the rules are applicable to carboranes. This can be explained due to a frontier orbital treatment.[10] Additionally there are isolobal transition-metal units. For example, Fe(CO)3 provides 2 electrons. The derivation of this is briefly as follows:
Transition metal clusters use the d orbitals for bonding. Thus, they have up to nine bonding orbitals, instead of only the four present in boron and main group clusters.[12][13] PSEPT also applies to metallaboranes
Owing their large radii, transition metals generally form clusters that are larger than main group elements. One consequence of their increased size, these clusters often contain atoms at their centers. A prominent example is [Fe6C(CO)16]2-. In such cases, the rules of electron counting assume that the interstitial atom contributes all valence electrons to cluster bonding. In this way, [Fe6C(CO)16]2- is equivalent to [Fe6(CO)16]6- or [Fe6(CO)18]2-.[14]
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(help) These notes contained original material that served as the basis of the sections on the 4n, 5n, and 6n rules.