Versatile Reactivity of Bridged Pentelidene Complexes toward Secondary and Tertiary Phosphines

The reaction of the phosphinidene complex [Cp*P­{W­(CO)₅}₂] (1a) with secondary and tertiary phosphines, respectively, proceeds via W­(CO)₅ elimination to form the phosphoranylidene complexes [{W­(CO)₅}­(Cp*)­P-P­(H)ⁱPr₂] (2), [{W­(CO)₅}­(Cp*)­P-PMeⁱPr₂] (7), and [{W­(CO)₅}­(Cp*)­P-PEt₃] (9). Other novel types of products, the phosphine-coordinated bridged parent phosphinidene complexes [{W­(CO)₅}₂(H)­P-PMeⁱPr₂] (6a) and [{W­(CO)₅}₂(H)­P-PEt₃] (8a), are obtained by elimination of 1,2,3,4-tetramethylfulvene. The latter reaction path is predominantly found for the arsinidene complex [Cp*As­{W­(CO)₅}₂] (1b) to yield [{W­(CO)₅}₂(H)­As-PHⁱPr₂] (4) upon reaction with HPⁱPr₂ and, with tertiary phosphines, the products [{W­(CO)₅}₂(H)­As-PMeⁱPr₂] (6b) and [{W­(CO)₅}₂(H)­As-PEt₃] (8b). If a secondary phosphine coordinates to a bridged parent pentelidene complex, Cp*H elimination occurs to form either HP­[PⁱPr₂{W­(CO)₅}]₂ (3) or the phosphine-substituted diarsene complex W­(CO)₅[AsPⁱPr₂{W­(CO)₅}]₂ (5). Each of the new products has been characterized by X-ray structure analysis, NMR, and mass spectroscopy. In each case as a first step the Lewis acid/base adducts are formed, which was monitored by ³¹P NMR spectroscopy. The different reaction pathways of the electrophilic pentelidene complexes [Cp*E­{W­(CO)₅}₂] (E = P, As) have been emphasized by extended DFT calculations.