Abstract
A new organic-functionalized Cu-based Anderson-type polyoxomolybdate, namely (C(7)H(15)N(4))(2)[Na(H(2)O)(4)](2)[C(6)H(12)CuMo(6)N(2)O(24)]·2(H(2)O) (Cu(II)-POM), was synthesized via a simple one-pot reaction and subsequently characterized using a range of analytical and spectral techniques. Structural investigation by single crystal X-ray diffraction analysis revealed that the polyanion component of the synthesized compound (i.e. [C(6)H(12)CuMo(6)N(2)O(24)](4-)) possesses a δ-isomer Anderson-type structure, which is surrounded by four lattice water molecules and four [C(7)H(15)N(4)-NaH(15)(H(2)O)(8)](4+) cations in the crystal packing arrangement. The resulting double-sided tris-functionalized Anderson-type compound can function as highly effective heterogeneous photocatalysts for the copper(I)-catalyzed Huisgen azide-alkyne cycloaddition (Cu-AAC) reaction of terminal alkyne, benzyl halides, and sodium azide (acts as the azidonation and reducing agent) in aqueous media. Ultraviolet light irradiation enhances the catalytic activity of Cu(II)-POM ~ 4.4 times of the "off" situation under reaction conditions of 0.00239 mmol cat., 80 °C, 8 h, 2 mL H(2)O, So that the isolated yields for the AAC reaction involving a variety of terminal alkynes and benzyl halides using the Cu(II)-POM catalyst ranged between 19-97%. The current study is the first report about using an efficient and economical Cu(II)-POM/UV/NaN(3) catalytic system in the Cu-AAC reaction and reveals its significant potential for applying to other Cu(I)-catalyzed reactions.