Organoboron chemistry


Organoboron chemistry or organoborane chemistry studies organoboron compounds, also called organoboranes. These chemical compounds combine boron and carbon; typically, they are organic derivatives of borane, as in the trialkyl boranes.
Organoboranes and -borates enable many chemical transformations in organic chemistry — most importantly, hydroboration and carboboration. Most reactions transfer a nucleophilic boron substituent to an electrophilic center either inter- or intramolecularly. In particular, α,β-unsaturated borates and borates with an α leaving group are highly susceptible to intramolecular 1,2-migration of a group from boron to the electrophilic α position. Oxidation or protonolysis of the resulting organoboranes generates many organic products, including alcohols, carbonyl compounds, alkenes, and halides.

Properties of the B-C bond

The C-B bond has low polarity. Alkyl boron compounds are in general stable, though easily oxidized.
Boron often forms electron-deficient compounds without a full octet, such as the triorganoboranes. These compounds are strong electrophiles, but typically too sterically hindered to dimerize. Electron donation from vinyl and aryl groups can lend the C-B bond some double bond character.

Classes of organoboron compounds

Organoboranes

The most-studied class of organoboron compounds has the formula BRnH3−n. These compounds are catalysts, reagents, and synthetic intermediates. Except a few bulky derivatives, the primary and secondary hydrides are, like diborane itself, strongly Lewis acidic and dimerize in condensed phases. The trialkyl and triaryl derivatives, e.g. triethylboron, are typically only weakly Lewis acidic, and form monomers with a trigonal, planar boron center.
Monoalkyl boranes are relatively rare. When the alkyl group is small, such as methyl, monoalkylboranes often redistribute to mixtures of diborane and di- and trialkylboranes. One example of an isolable primary borane is thexylborane, produced by the hydroboration of tetramethylethylene: A chiral example is monoisopinocampheylborane, obtained by hydroboration of ‐α‐pinene with borane dimethyl sulfide. Although often written as IpcBH2, it is a dimer, 2.
Dialkylboranes are also rare with small alkyls. One common preparation reduces dialkylhalogenoboranes with metal hydrides. An important application in organic synthesis is transmetallation to form organozinc compounds. Nevertheless, some diaryl and dialkylboranes are well known. Dimesitylborane is a dimer that reacts only slowly with simple terminal alkenes. It adds to alkynes to give alkenylboranes. A hindered dialkylborane is disiamylborane, abbreviated Sia2BH, also a dimer. Owing to its steric bulk, it selectively hydroborates less hindered, usually terminal alkenes in the presence of more substituted alkenes. Disiamylborane must be freshly prepared as its solutions can only be stored at 0 °C for a few hours. Dicyclohexylborane Chx2BH exhibits improved thermal stability than Sia2BH.
A versatile dialkylborane is 9-BBN. Also called "banana borane", it exists as a dimer. It can be distilled without decomposition at 195 °C. Reactions with 9-BBN typically occur at 60–80 °C, with most alkenes reacting within one hour. Tetrasubstituted alkenes add 9-BBN at elevated temperature. Hydroboration of alkenes with 9-BBN proceeds with excellent regioselectivity. It is more sensitive to steric differences than Sia2BH, perhaps because of it rigid C8 backbone. 9-BBN is more reactive towards alkenes than alkynes.

Oxyacids and esters

Compounds of the type BRn3-n are called borinic esters, boronic esters, and borates . Boronic acids are key to the Suzuki reaction. Trimethyl borate, debatably not an organoboron compound, is an intermediate in sodium borohydride production.

Adducts

Boranes and borinic, boronic, and borate esters all form adducts with appropriate Lewis bases.
Strong bases do not deprotonate boranes of the form R2BH. Instead these reactions afford the octet-complete adduct R2HB-base.
NHCs and boranes form stable NHC-borane adducts. Triethylborane adducts can be synthesised directly from the imidazolium salt and lithium triethylborohydride.

Polyhedral clusters

Boron is renowned for cluster species, e.g. dodecaborate 2-. Such clusters have many organic derivatives. One example is 2- and its radical derivative . Related cluster compounds with carbon vertices are carboranes; the best known is orthocarborane, C2B10H12. Carboranes have few commercial applications. Anionic derivatives such as 2−, called dicarbollides, ligate similarly to cyclopentadienide.
Borane cluster structures are built from the triangular 3 unit, which is almost unknown in isolation. However, the corresponding aromatic dianion,, forms from careful dehalogenation of a RNBCl2 species.

Boryl complexes and radicals

with metal-boron bonds are boryl complexes, corresponding to the notional boryl anion R2B, although the latter cannot be produced through deprotonation. In one synthesis, the boryl anion moiety arose through lithium-halogen exchange: As shown, the product is isoelectronic to an N-heterocyclic carbene.
Related ligands are borylenes.

Unsaturated compounds

with a boron–carbon double bond are rare. One example, HB=CH2, can be detected at low temperature. The derivative CH3B=C2 is fairly stable, but prone to cyclodimerisation.
Some boron-substituted heterocycles are aromatic, but very few such arenes are stable. In borabenzene, boron replaces one CH center in benzene. Borabenzene and derivatives invariably appear as adducts, e.g., C5H5B-pyridine. The cyclic compound borole, a structural analog of pyrrole, has not been isolated, but substituted derivatives are known. The cyclic compound borepin has been isolated and is aromatic.
Boron-boron multiple bonds are rare, although doubly-bonded dianions have been known since the 1990s. Neutral analogues use NHC adducts, such as the following diborane derivative:
Each boron atom has an attached proton and is coordinated to a NHC carbene.
A reported diboryne and boranylium ions are based on similar chemistry,
A compound with the B≡C triple bond was synthesized for the first time in 2025.

Synthesis

From Grignard reagents

Simple organoboranes such as triethylborane or trisboron can be prepared from trifluoroborane and the ethyl or pentafluorophenyl Grignard reagent. Further carbanion addition will effect a borate.
Boronic acids RB2 react with potassium bifluoride K to form trifluoroborate salts K, precursors to nucleophilic alkyl and aryl boron difluorides, ArBF2:

From alkenes

In hydroboration, alkenes insert into borane B-H bonds, with anti-Markovnikov stereochemistry. Hydroboration occurs stereospecifically syn — on the same alkene face. The transition state for this concerted reaction can be visualized as a square with the corners occupied by carbon, carbon, hydrogen and boron, maximizing overlap between the olefin p-orbitals and the empty boron orbital.
Hydroboration with borane equivalents converts only 33% of the starting olefin to product — boron-containing byproducts consume the remainder. The chelate effect improves that ratio for cyclic boron-containing reagents. One common cyclic organoboron reagent is 9-BBN.

By borylation

Metal-catalyzed borylation reactions produce an organoboron compound from aliphatic or aromatic C-H sigma bonds via a transition-metal catalyst. A common reagent is bisdiboron.

From other boron compounds

reacts with alkylboranes to form an unstable borane carbonyl. Then an alkyl substituent migrates from boron to the carbonyl carbon. For example, homologated primary alcohols result from organoboranes, carbon monoxide, and a reducing agent :

Alkenylboranes

Alkynylboranes attack electrophiles to give trans alkenylboranes, as in the first step of this olefin synthesis:

Reactions

The key property of organoboranes and borates is their susceptibility to reorganization. These compounds possess boron–carbon bonds polarized toward carbon. The boron-attached carbon is nucleophilic; in borates, the nucleophicity suffices for intermolecular transfer to an electrophile.
Boranes alone are generally not nucleophilic enough to transfer an R group intermolecularly. Instead, the group 1,2-migrates to an electrophilic carbon attached to boron, especially if that carbon is unsaturated or bears a good leaving group:
An organic group's migration propensity depends on its ability to stabilize negative charge: alkynyl > aryl ≈ alkenyl > primary alkyl > secondary alkyl > tertiary alkyl. Bisborane and 9-BBN are often hydroboration reagents for this reason — only the hydroborated olefin is likely to migrate upon nucleophilic activation.
Migration retains configuration at the migrant carbon and inverts it at the terminus. The resulting reorganized borane can then be oxidized or protolyzed to a final product.

Protonolysis

Organoboranes are unstable to Brønsted–Lowry acids, deboronating in favor of a proton. Consequently, organoboranes are easily removed from an alkane or alkene substrate, as in the second step of this olefin synthesis:

Addition to halocarbonyls

α-Halo enolates are common nucleophiles in borane reorganization. After nucleophilic attack at boron, the resulting ketoboronate eliminates the halogen and tautomerizes to a neutral enolborane. A functionalized carbonyl compound then results from protonolysis, or quenching with other electrophiles:
Because the migration is stereospecific, this method synthesizes enantiopure α-alkyl or -aryl ketones.
α-Haloester enolates add similarly to boranes, but with lower yields:
Diazoesters and diazoketones remove the requirement for external base. α,α'-Dihalo enolates react with boranes to form α-halo carbonyl compounds that can be further functionalized at the α position.