Abstract
The first “naked” (Lewis base‐free) cationic Ca amidinate complex [tBuAmDIPPCa(C6H6)]+[B(C6F5)4]– was prepared in 62 % yield {tBuAmDIPP = tBuC(N–DIPP)2; DIPP = 2,6‐diisopropylphenyl} by reaction of [tBuAmDIPPCaH]2 with [Ph3C]+[B(C6F5)4]– in chlorobenzene. The ether‐free complex tBuAmDIPPCaN(SiMe3)2 was obtained by removal of diethyl ether from its ether adduct. Crystal structures show that the amidinate ligand in both complexes is N,Aryl‐chelating. In this coordination mode the bulk of the amidinate ligand is comparable to that of a DIPP‐substituted β‐diketiminate ligand. Isomers with N,N‐coordinating amidinate ligands are circa 15 kcal/mol higher in energy and this coordination mode is only present in case additional ether ligands compensate for energy loss or in case of space limitation at the metal, e.g. in homoleptic (tBuAmDIPP)2Ca. A series of four Ca amidinate complexes, tBuAmDIPPCaX, were tested in the catalytic hydroboration of ketones and aldehydes by pinacolborane (HBpin). Catalytic activities increase for X– = I– < B(C6F5)4– < (Me3Si)2N– ≈ H–. For catalysts with unreactive anions, like I– or B(C6F5)4–, catalyst performance increases with the Lewis acidity of the metal and a mechanism is proposed in which HBpin and ketone coordinate to the Ca2+ ion which is followed by direct hydroboration. The more active catalysts with X– = (Me3Si)2N– or H– likely operate through a mechanism which involves intermediate metal hydride (or borate) complexes.
Highlights
Over the last decades, research on alkaline earth metal based homogeneous catalysis gained momentum and conquered fields, which were long thought to be the exclusive domain of transition metal catalysis.[1,2,3,4] often still not on par with their classical transition metal based counterparts, alkaline earth metals make up for lower catalytic activity of their complexes by price, availability and non-toxicity, at least in case of magnesium and calcium
For catalysts with unreactive anions, like I– or B(C6F5)4, catalyst performance increases with the Lewis acidity of the metal and a mechanism is proposed in which hydroboration of ketones and aldehydes by pinacolborane (HBpin) and ketone coordinate to the Ca2+ ion which is followed by direct hydroboration
We have prepared a series of Ca amidinate complexes with the amidinate ligand tBuAmDIPP
Summary
Research on alkaline earth metal based homogeneous catalysis gained momentum and conquered fields, which were long thought to be the exclusive domain of transition metal catalysis.[1,2,3,4] often still not on par with their classical transition metal based counterparts, alkaline earth metals make up for lower catalytic activity of their complexes by price, availability and non-toxicity, at least in case of magnesium and calcium. For catalysts with unreactive anions, like I– or B(C6F5)4–, catalyst performance increases with the Lewis acidity of the metal and a mechanism is proposed in which HBpin and ketone coordinate to the Ca2+ ion which is followed by direct hydroboration.
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