Organolead compound

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Organolead compounds are chemical compounds containing a chemical bond between carbon and lead. Organolead chemistry is the corresponding science. The first organolead was hexaethyldilead synthesised in 1858.^[1] Sharing the same group with carbon, lead is tetravalent.

Going down the carbon group the C–X (X = C, Si. Ge, Sn, Pb) bond becomes weaker and the bond length larger. The C–Pb bond in tetramethyllead is 222 pm long with a dissociation energy of 204 kcal/mol (854 kJ/mol). For comparison the C–Sn bond in tetramethyltin is 214 pm long with dissociation energy 297 kcal/mol (1.24 MJ/mol).

By far the most important organolead compound is tetraethyl lead used as an anti-knocking agent. The most important lead reagents for introducing lead are lead tetraacetate and lead chloride.

The use of organoleads is limited partly due to their toxicity although it is remarked^[1] that the toxicity is only 10% of that of palladium compounds.

Synthesis

Organolead compounds can be derived from Grignard reagents and lead chloride. For example methylmagnesium chloride reacts with lead chloride to tetramethyllead, a water-clear liquid with boiling point 110 °C and density 1.995 g/cm³. Reaction of lead chloride with the lithium salt of pentamethylcyclopentadiene gives the lead metallocene.

Certain arene compounds react directly with lead tetraacetate to aryl lead compounds in an electrophilic aromatic substitution. For instance anisole with lead tetraacetate forms p-methoxyphenyllead triacetate in chloroform and dichloroacetic acid:^[1]

Image:AryltriacetateSynthesis.png

Reactions

The C–Pb bond is weak and for this reason homolytic cleavage of organolead compounds to free radicals is easy. In its anti-knocking capacity, its purpose is that of a radical initiator. General reaction types of aryl and vinyl organoleads are transmetalation for instance with boronic acids and acid-catalyzed heterocyclic cleavage. Organoleads find use in coupling reactions between arene compounds. They are more reactive than the likewise organotins and can therefore be used to synthesise sterically crowded biaryls.

Aryllead triacetates

The lead substituent in p-methoxyphenyllead triacetate is displaced by carbon nucleophiles such as the phenol 2,4,6-trimethylphenol (mesitol) exclusively at the aromatic ortho position:^[1]

Image:PhenolLeadphenyltriacetateReaction.png

The reaction requires the presence of a large excess of a coordinating amine such as pyridine which presumably binds to lead in the course of the reaction. The reaction is insensitive to radical scavengers and therefore a free radical mechanism can be ruled out. The reaction mechanism is likely to involve nucleophilic displacement of an acetate group by the phenolic group to a diorganolead intermediate which in some related reactions can be isolated. The second step is then akin to a Claisen rearrangement except that the reaction depends on the electrophilicity (hence the ortho preference) of the phenol.

The nucleophile can also be the carbanion of a β-dicarbonyl compound (please fix my picture):^[1]

Image:ArylleadCaryllation.png

The carbanion forms by proton abstraction of the acidic α-proton by pyridine (now serving a double role) akin to the Knoevenagel condensation. This intermediate displaces an acetate ligand to a diorganolead compound and again these intermediates can be isolated with suitable reactants as unstable intermediates. The second step is reductive elimination with formation of a new C–C bond and lead(II) acetate.

See also

CH

He

CLi

CBe

CB

CC

CN

CO

CF

Ne

CNa

CMg

CAl

CSi

CP

CS

CCl

Ar

CK

CCa

CSc

CTi

CV

CCr

CMn

CFe

CCo

CNi

CCu

CZn

CGa

CGe

CAs

CSe

CBr

Kr

CRb

CSr

CY

CZr

CNb

CMo

CTc

CRu

CRh

CPd

CAg

CCd

CIn

CSn

CSb

CTe

CI

Xe

CCs

CBa

CHf

CTa

CW

CRe

COs

CIr

CPt

CAu

CHg

CTl

CPb

CBi

CPo

CAt

Rn

Fr

Ra

Rf

Db

Sg

Bh

Hs

Mt

Ds

Rg

Uub

Uut

Uuq

Uup

Uuh

Uus

Uuo

↓

La

Ce

Pr

Nd

Pm

Sm

Eu

Gd

Tb

Dy

Ho

Er

Tm

Yb

Lu

Ac

Th

Pa

CU

Np

Pu

Am

Cm

Bk

Cf

Es

Fm

Md

No

Lr

Chemical bonds to carbon

Core organic chemistry	many uses in chemistry.
Academic research, but no widespread use	Bond unknown / not assessed.

References

ja:有機鉛化合物

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