The key property of organoboranes (R3B) and borates (R4B−, generated via addition of R− to R3B) 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. Bis(norbornyl)borane 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 (presumably
sp3-hybridized) 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.
Addition to carbonyl functional groups In allylboration, an
allylborane adds across an
aldehyde or
ketone with an
allylic shift, and can then be converted to a
homoallylic alcohol during
workup. The reaction is much slower with ketones than aldehydes. For example, in Nicolaou's
epothilones synthesis, asymmetric allylboration (with an allylborane derived from chiral
alpha-pinene) is the first step in a two-carbon
homologation to
acetogenin: Trifluoroborate salts are stabler than boronic acids and selectively alkylate
aldehydes:
Oxygenation The
hydroboration-oxidation reaction pair oxidizes the borane to an
alcohol with
hydrogen peroxide or to a
carbonyl group with
chromium oxide. Oxidation of an alkenylborane gives a boron-free enol.
Halogenation Organoborane activation with hydroxide or alkoxide and treatment with X2 yields haloalkanes. With excess base, two of the three alkyl groups attached to the boron atom may convert to halide, but
disiamylborane permits only halogenation of the hydroborated olefin: Treatment of an alkenylborane with iodine or bromine induces migration of a boron-attached organic group. Alkynyl groups migrate selectively, forming enynes after treatment with sodium acetate and hydrogen peroxide:
Transmetalation and coupling Organoboron compounds also
transmetalate easily, especially to
organopalladium compounds. In the
Suzuki reaction, an
aryl- or
vinyl-
boronic acid couples to an
aryl- or
vinyl-
halide through a
palladium(0) complex catalyst:R1-BY2{} + R2-X -> [\underset{catalyst} {Pd}][\text{Base}] R1-R2
Reducing agents Borane hydrides such as
9-BBN and
L-selectride (lithium tri(
sec-butyl)borohydride) are
reducing agents. An
asymmetric catalyst for
carbonyl reductions is the
CBS catalyst, which relies on boron coordination to the carbonyl oxygen. == Other synthetic applications ==