화학공학소재연구정보센터
Inorganic Chemistry, Vol.53, No.16, 8770-8785, 2014
Photophysical Responses in Pt2Pb Clusters Driven by Solvent Interactions and Structural Changes in the Pb-II Environment
Two types of Pt2Pb luminescent clusters were successfully prepared by the reaction of [Pt(C6F5)(bzq)(OCMe2)] (1) and [Pt(C6F5)-(ppy)(dmso)] (2) with [Pb(SpyR-5)(2)] (R = H, CF3). Thus, whereas 5 (ppy, Spy) is generated through coordination of the pyridine-N atoms to the Pt centers, the formation of 3, 4 (bzq), and 6 (ppy, SpyCF(3)) is accompanied by a formal thiolate transfer from Pb-II to Pt-II, keeping the two N atoms in the primary environment of the lead. In 5, the neutral Pb center adopts a rather stable and symmetrical "Pt2S2" coordination sphere supplemented by two Pb.. F-0 contacts, whereas for the remaining species several pseudopolyrnorphs were found depending on the solvent (3, 4) and crystallization conditions (6). This structural diversity relies on changes in the coordination mode of the SpyR ligands (mu-kS,N/mu-k(3)S,N,S), intermetallic Pt-Pb bonds, and secondary infra- and intermolecular contacts induced by Pb-solvent binding. Notably, the changes, which entail a slight tuning of the stereochemical activity of the lone pair, have also a remarkable impact on the emissive state (L-3'CCT/L-3'LCT, SpyR -> Pb,Pt/(C<^>N) in nature). Clusters 3 and 4 display a distinct and fast reversible blue shift vapoluminescent response (4 shows also color changes) to donor solvents, correlated with changes in the environment of the Pb-II ion (asymmetric hemidirected to more symmetric holodirected) upon solvent binding and, additionally, in 4 with modifications in the crystal packing, as confirmed by XRD and supported by TD-DFT calculations. 5 and 6 do not show a vapoluminescent response. However, for 6, three different and interconvertible forms, a symmetrical form (yellow 6-y) and two asymmetrical forms with a rather short Pt-Pb bond (pale orange 6 center dot acetone and orange 6-o), exhibiting different emissions were found. Notably, slow crystallization and low concentration favor the formation of the thermodynamically more stable yellow form, whereas fast crystallization gives rise to orange solids with a remarkable red shift of the emission. Interestingly, 6 also exhibits reversible mechanochromic color and luminescence changes.