Sodium tetraphenylborate

Synthesis and structure

Sodium tetraphenylborate is synthesized by the reaction between sodium tetrafluoroborate and phenylmagnesium bromide: :NaBF4 + 4 PhMgBr → 2 MgBr2 + 2 MgF2 + NaBPh4 (where Ph = phenyl) A related synthesis involves the use of phenylsodium in place of the Grignard reagent.

Unlike smaller counteranions, such as nitrate and the halides, tetraphenylborate confers lipophilicity to its salts. Many analogous tetraarylborates have been synthesized, containing both electron-rich and electron-deficient aryl groups.

The anhydrous salt adopts a polymeric structure in the solid state consisting of Na+-phenyl interactions. As such the salt could be classified as an organosodium compound.

Use in chemical synthesis

Preparation of ''N''-acylammonium salts

Addition of sodium tetraphenylborate to a solution of a tertiary amine and an acid chloride in acetonitrile gives the acylonium salt by precipitating NaCl from the reaction mixture. This method has a broad scope: :RC(O)Cl + R'3N + NaB(C6H5)4 → [RC(O)NR'3][B(C6H5)4] + NaCl

Sodium tetraphenylborate is also employed as a phenyl donor in palladium-catalyzed cross-coupling reactions involving vinyl and aryl triflates to give arylalkenes and biaryl compounds in good yields and under mild conditions, respectively.

Use in coordination chemistry

Tetraphenylborates are often studied in organometallic chemistry because of their good solubility in nonpolar solvents and their crystallinity. For example, the homoleptic trimethylphosphite complexes {M[P(OCH3)3]5}2+ (Ni, Pd, and Pt) have been prepared as their tetraphenylborate salts. Similarly, sodium tetraphenylborate has been used to isolate complexes containing dinitrogen ligands. In the reaction below, sodium tetraphenylborate allows N2 to displace the chloride ligand, which is removed from solution as a precipitate of sodium chloride: :FeHCl(diphosphine)2 + NaB(C6H5)4 + N2 → [FeH(N2)(diphosphine)2]B(C6H5)4 + NaCl The use of tetraphenylborate is limited to non-acidic cations. With strong acids, the anion undergoes protonolysis to give triphenylborane and benzene: :H+ + B(C6H5)4− → B(C6H5)3 + C6H6

Related tetraorganoborates

Weakly coordinating anions often are based on tetraarylborates, with electronegative substituents. Examples include B(C6F5)4− and Brookhart's acid containing the tetrakis[3,5-bis(trifluoromethyl)phenyl]borate anion.

References

References

1. R. M. Washburn, F. A. Billig, "Tetraarylboron Compounds"US Patent 3,311,662.
2. 10.1021/om200943n
3. (1992). "Preparation and characterization of crystalline N-acylammonium salts". [[J. Org. Chem.]].
4. (1992). "Palladium-catalyzed cross-coupling reactions of vinyl and aryl triflates with tetraarylborates". Tetrahedron Letters.
5. J. P. Jesson, M. Cushing, [[Steven Ittel. (2007). "Inorganic Syntheses".
6. (1974). "Inorganic Syntheses".
7. Tianshu Li, Alan J. Lough, Cristiano Zuccaccia, Alceo Macchioni, and Robert H. Morris "An acidity scale of phosphonium tetraphenylborate salts and ruthenium dihydrogen complexes in dichloromethane" Can. J. Chem. 84(2): 164–175 (2006). {{doi. 10.1139/V05-236.