Family of penta- and hexanuclear metallasilsesquioxanes: Synthesis, structure and catalytic properties in oxidations

“…This allowed us to isolate products of different nuclearity from two to nine, , , and different molecular topology. Sometimes, molecular topology and core nuclearity is governed by a promotive action of additional organic (P‐ or N‐based) ligands or solvent molecules intentionally introduced into the reaction medium. However, general regularities underlying the self‐assembly processes in this extremely complex system remain elusive, even though the total number of different CLMS structure types are rapidly increasing.…”

Heptanuclear Cage Cu^II‐Silsesquioxanes: Synthesis, Structure and Catalytic Activity

“…This allowed us to isolate products of different nuclearity from two to nine, , , and different molecular topology. Sometimes, molecular topology and core nuclearity is governed by a promotive action of additional organic (P‐ or N‐based) ligands or solvent molecules intentionally introduced into the reaction medium. However, general regularities underlying the self‐assembly processes in this extremely complex system remain elusive, even though the total number of different CLMS structure types are rapidly increasing.…”

Heptanuclear Cage Cu^II‐Silsesquioxanes: Synthesis, Structure and Catalytic Activity

“…10 For example, their high activity was reported for such reactions of high demand as olefin 11 or ringopening polymerization, 12 olefin epoxidation, 13 polycarbonate synthesis, 14 and a Meerwein−Ponndorf reaction, 15 as well as for hydroformylation. 16 In turn, our team reported on the catalytic activity of cagelike metallasilsesquioxanes in oxidative hydrocarbon functionalization 17 and amidation 18 reactions. Very recently, some of us presented the first example of the successful testing of CLMSs, including additional organic (phosphorusbased 19 ) ligands in such oxidative reactions.…”

Si₁₀Cu₆N₄Cage Hexacoppersilsesquioxanes Containing N Ligands: Synthesis, Structure, and High Catalytic Activity in Peroxide Oxidations

“…Mentioned above non-rigidity of siloxanolate ligands in the procedure of CLMS' assembly found additional evidence during the study of the synthesis of Cu-silsesquioxane in dimethylformamide (DMF) media (Scheme 1, complex 2). This reaction allows unprecedented pentanuclear CLMS 2 (PhSiO 1,5 ) 6 (PhSiO 1,5 ) 7 (HO 0.5 ) 2 (CuO) 5 (O 0.25 ) 2 (phen) 3 (Figure 2, top), which is very unlike pentacopper (PhSiO 1.5 ) 10 (CuO) 5 -CLMSs, reported earlier by us [54] and the Y. Kononevich team [52]. Most likely, this difference was due to the participation of phenanthroline ligands in the reaction reporting here.…”

“…A ratio between interacting silanolate [(PhSiO 1.5 )(NaO 0.5 )] x and copper(II) chloride was oriented to let some amount of sodium ions not to be replaced by copper ions. The resulted Cu/Na mixture in the reaction system allowed us to expect a formation of an unusual cage product [11,12,[38][39][40], instead of widespread prismatic forms of Cu-only products [15,42,[52][53][54]. Indeed, this choice of ratio provokes the isolation of the nontrivial "double-ligated" Cu 4 Na 4 product 1 (Scheme 1, Figure 1).…”

New Cu4Na4- and Cu5-Based Phenylsilsesquioxanes. Synthesis via Complexation with 1,10-Phenanthroline, Structures and High Catalytic Activity in Alkane Oxidations with Peroxides in Acetonitrile