Electrodeposition of tin and tin alloys from electrolytes containing tin(II) and pyrophosphates is an important process in metal finishing, but the nature of the tin pyrophosphate complexes present in these solutions in various pH regions has remained unknown. Through solubility and pH studies, IR and P-31 and Sn-119 NMR spectroscopic investigations of solutions obtained by dissolving Sn2P2O7 in equimolar quantities of either Na4P2O7 center dot 10H(2)O or K4P2O7 the formation of anionic 1:1 complexes {[Sn-(P2O7)]}(n)(2n-) has now been verified and the molecular structures of the monomer (n = 1) and the dimer (n = 2) have been calculated by density functional theory (DFT) methods. Whereas the alkali pyrophosphates Na/K4P2O7 give strongly alkaline aqueous solutions (pH similar to 13), because of partial protonation of the [P2O7](4-) anion, the [Sn(P2O7)](2-) anion is not protonated and the solutions of Na/K-2[Sn(P2O7)] are almost neutral (pH similar to 8). The monomeric dianion appears to have a ground state with C-2v symmetry with the Sn atom in a square pyramidal coordination and the lone pair of electrons in the apical position, while the dimer approaches C-2 symmetry with the Sn atoms in a rhombic pyramidal coordination, also with a sterically active lone pair. A comparison of experimental and calculated IR details favors the monomer as the most abundant species in solution. With an excess of pyrophosphate, 3:2 and 2:1 complexes (P2O7):(Sn) are first formed, which, in the presence of more pyrophosphate, undergo rapid ligand exchange on the NMR time scale. The structure of the 2:1 complex [Sn(P2O7)(2)](6-) was calculated to have a pyramidal complexation by two 1,5-chelating pyrophosphate ligands. Neutralization of these alkaline solutions by sulfuric or sulfonic acids (H2SO4, MeSO3H), as also practiced in electroplating, appears to afford the tin(II) hydrogen pyrophosphates [Sn(P2O7H)](-) and [Sn(H2P2O7)](0). The molecular structures of the mononuclear model units have also been calculated and were shown to have an unsymmetrical complexation and to feature trigonal pyramidal (pseudotetrahedral) coordination. NMR observations have shown that, contrary to the results obtained for Sn-II compounds, Sn-IV as present in K2SnO3 or its hydrated form (K2Sn(OH)(6)) does not form a pyrophosphate complex in aqueous solution near pH 7. There is also no interference of sulfite.

• 出版日期2012-8-20