Definitions

boron-hydride

borane

[bawr-eyn, bohr-]

Any of a homologous series of inorganic compounds of boron and hydrogen or their derivatives. The ability of boranes to form three-centre bonds (one pair of electrons is shared between three atoms) and covalent bonds allows them to form complex structures called polyhedrons, which can be considered as deltahedrons (polyhedrons with triangular faces) or deltahedral fragments. Low-molecular-weight boranes are spontaneously flammable in air, although reactivity generally decreases with increasing molecular weight. Boranes are sources of high-energy fuels for rockets and jet aircraft.

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In chemistry, a borane is a chemical compound of boron and hydrogen. The boranes comprise a large group of compounds with the generic formulae of BxHy. These compounds do not occur in nature. Many of the boranes readily oxidise on contact with air, some violently. The parent member BH3 is called borane, but it is known only in the gaseous state, and dimerises to form diborane, B2H6. The larger boranes all consist of boron clusters that are polyhedral, some of which exist as isomers. For example, isomers of B20H26 are based on the fusion of two 10-atom clusters.

The most important boranes are diborane B2H6, pentaborane B5H9, and decaborane B10H14.
The development of the chemistry of boron hydrides led to new experimental techniques and theoretical concepts. Boron hydrides have been studied as potential fuels, for rockets and for automotive uses.

Over the past several decades, the scope of boron hydride chemistry has grown to include cages containing atoms other than boron, such as carbon in the carboranes and metals in the metallaboranes, wherein one or more boron atoms are substituted by metal atoms.

Generic formulae of boranes

The four series of single-cluster boranes have the following general formulae, where "n" is the number of boron atoms:-
Type formula notes
closo− BnHn2− No neutral BnHn+2 boranes are known
nido− BnHn+4
arachno− BnHn+6
hypho− BnHn+8 only adducts established

There also exists a series of substituted neutral hypercloso-boranes that have the theoretical formulae BnHn. Examples include B12(OCH2Ph)12, which is a stable derivative of hypercloso-B12H12.

Naming conventions

The naming of neutral boranes is illustrated by the following examples, where the Greek prefix shows the number of boron atoms and the number of hydrogen atoms is in brackets:-

  • B5H9 pentaborane(9)
  • B6H12 hexaborane(12)


The naming of anions is illustrated by the following, where the hydrogen count is specified first followed by the boron count, and finally the overall charge in brackets:-

  • B5H8 octahydropentaborate(1−)


Optionally closo− nido− etc (see above) can be added:-

  • B5H9, nido−pentaborane(9)
  • B4H10, arachno−tetraborane(10)
  • B6H62−, hexahydro−closo−hexaborate(2−)

Understandably many of the compounds have abbreviated common names.

Cluster types

It was realised in the early 1970s that the geometry of boron clusters are related and that they approximate to deltahedra or to deltahedra with one or more vertices missing. The deltahedra that are found in borane chemistry are (using the names favoured by most chemists):--
deltahedron vertices
Trigonal bipyramid 5
Octahedron 6
Pentagonal bipyramid 7
Dodecahedron 8
Tricapped trigonal prism 9
Bicapped square antiprism 10
Octadecahedron 11
Icosahedron 12
One feature of these deltahedra is that boron atoms at the vertices may have different numbers of boron atoms as near neighbours. For example, in the pentagonal bipyramid, 2 borons have 3 neighbors, 3 have 4 neighbours, whereas in the octahedral cluster all vertices are the same, each boron having 4 neighbours. These differences between the boron atoms in different positions are important in determining structure, as they have different chemical shifts in the 11B NMR spectra.

B6H10 is a typical example. Its geometry is, in essence, a 7-boron framework (pentagonal bipyramid), missing a vertex that had the highest number of near neighbours, e.g., a vertex with 5 neighbours. The extra hydrogen atoms bridge around the open face. A notable exception to this general scheme is that of B8H12, which would be expected to have a nido- geometry (based on B9H92− missing 1 vertex), but is similar in geometry to B8H14, which is based on B10H102−.
The names for the series of boranes are derived from this general scheme for the cluster geometries:-

  • hypercloso- (from the Greek for "over cage") a closed complete cluster, e.g., B8Cl8 is a slightly distorted dodecahedron
  • closo- (from the Greek for "cage") a closed complete cluster, e.g., icosahedral B12H122−
  • nido- (from the Latin for "nest") B occupies n vertices of an n+1 deltahedron, e.g., B5H9 an octahedron missing 1 vertex
  • arachno- (from the Greek for "spiders web") B occupies n vertices of an n+2 deltahedron e.g. B4H10 an octahedron missing 2 vertices
  • hypho- (from the Greek for "net") B occupies n vertices of an n+3 deltahedron possibly B8H16 has this structure, an octahedron missing 3 vertices
  • conjuncto- 2 or more of the above are fused together

Bonding in boranes

Boranes are electron-deficient and pose a problem for conventional descriptions of covalent bonding that involves shared electron pairs. BH3 is a trigonal planar molecule (D3h molecular symmetry). Diborane has a hydrogen-bridged structure, see the diborane article. The description of the bonding in the larger boranes formulated by William Lipscomb involved:

  • 3 center 2 electron B-H-B hydrogen bridges
  • 3-center 2-electron B-B-B bonds
  • 2-center 2-electron bonds (in B-B, B-H and BH2)

The styx number was introduced to aid in electron counting where s = count of 3-center B-H-B bonds; t = count of 3-center B-B-B bonds; y = count of 2-center B-B bonds and x = count of BH2 groups.
Lipscomb's methodology has largely been superseded by a molecular orbital approach, although it still affords insights. The results of this have been summarised in a simple but powerful rule, PSEPT, often known as Wade's rules, that can be used to predict the cluster type, closo-, nido-, etc. The power of this rule is its ease of use and general applicability to many different cluster types other than boranes. There are continuing efforts by theoretical chemists to improve the treatment of the bonding in boranes — an example is Stone's tensor surface harmonic treatment of cluster bonding. A recent development is four-center two-electron bond.

Chemistry of boranes

Properties and reactivity trends

Boranes are all colourless and diamagnetic. They are reactive compounds and some are pyrophoric. The majority are highly poisonous and require special handling precautions.closo−
There is no known neutral closo borane. Salts of the closo anions, BnHn2− are stable in neutral aqueous solution, and their stabilities increase with size. The salt K2B12H12 is stable up to 700o.nido−
Pentaborane(9) and decaborane(14) are the most stable nido−boranes, in contrast to nido−B8H12 that decomposes above -35o. arachno−
Generally these are more reactive than nido−boranes and again larger compounds tend to be more stable.

Synthesis and general reactivity

Borane BH3
This is an important intermediate in the pyrolosis of diborane to produce higher boranes. Diborane B2H6 and higher boranes
Diborane is made industrially by the reduction of BF3, and is the starting point for preparing the higher boranes.It has been studied extensively.General reactivity
Typical reactions of boranes are

Boranes can act as ligands in coordination compounds. Hapticities of η1 to η6 have been found, with electron donation involving bridging H atoms or donation from B-B bonds. For example, nido-B6H10 can replace ethene in Zeise's salt to produce Fe(η2-B6H10)(CO)4.
Boranes can react to form hetero-boranes, e.g., carboranes or metalloboranes (clusters that contain boron and metal atoms).

History

The development of the chemistry of boranes posed two challenges to chemists. First, new laboratory techniques had to be developed to handle these very reactive compounds; second, the structures of the compounds challenged the accepted theories of chemical bonding.
The German chemist Alfred Stock first characterized the series of boron-hydrogen compounds. His group developed the glass vacuum line and techniques for handling the compounds. However, exposure to mercury (used in mercury diffusion pumps and float valves) caused Stock to develop mercury poisoning, which he documented in the first scientific papers on the subject. The chemical bonding of the borane clusters was investigated by Lipscomb and his co-workers. Lipscomb was awarded the Nobel prize in Chemistry in 1976 for this work. PSEPT, (Wades rules) can be used to predict the structures of boranes.
Interest in boranes increased during World War II due to the potential of uranium borohydride for enrichment of the uranium isotopes. In the US, a team led by Schlesinger developed the basic chemistry of the boron hydrides and the related aluminium hydrides. Although uranium borohydride was not utilized for isotopic separations, Schessinger’s work laid the foundation for a host of boron hydride reagents for organic synthesis, most of which were developed by his student Herbert C. Brown. Borane-based reagents are now widely used in organic synthesis. For example, sodium borohydride is the standard reagent for converting aldehydes and ketones to alcohols. Brown was awarded the Nobel prize in Chemistry in 1979 for this work. In the 1950s and early '60s, the US and USSR investigated boron hydrides as high-energy fuels (ethylboranes, for example) for high speed aircraft, such as the XB-70 Valkyrie. The development of advanced surface-to-air missiles made the fast aircraft redundant, and the fuel programs were terminated, although triethylborane (TEB) was later used to ignite the engines of the SR-71 Blackbird.

General references

  1. Fox M.A., Wade K. Pure Appl. Chem. (2003),75,9, 1315

Footnotes

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