Methylaluminum‐Supported Rare‐Earth‐Metal Dihydrides

Abstract: Compounds combining the large rare-earth-metal (Ln) centers with the smallest anionic ligand, H À (hydrido), continue to pose challenging questions both in fundamental and applied chemistry. [1] The inherent bonding properties in solid-state binary LnH x phases (e.g., causing metallic behavior) as well as in ligand-supported molecular counterparts (revealing unique cluster chemistry, see Supporting Information) have been the focus of extensive research. Moreover, heterobimetallic solid-state materials, such as… Show more

“…X‐ray diffraction studies revealed the expected molecular structure (see Figure S1). The Y–N(imide) bond lengths in 2 average 2.126 Å (three independent molecules in the unit cell) and lie well within the expected range compared to previously reported LA‐supported yttrium imide complexes 12b,12c,18. As for the previously synthesized B ′‐type imide complexes,12b,12c compound 2 could not be converted into a terminal imide complex, neither thermally nor by addition of neutral Lewis bases like 1,4‐dioxane, pyridine, tmeda ( N , N , N′ , N′ ‐tetramethylethylenediamine), or DMAP.…”

“…We applied the superbulky monoanionic Tp t Bu,Me {hydrotris(3‐ tert ‐butyl‐5‐methylpyrazolyl)borate} ligand to enter [Ln=X](LA)‐type chemistry of the larger rare‐earth metals. Representative monolanthanide examples of the type A′ and B′ include [(Tp t Bu,Me )La(=CH 2 )(AlMe 3 ) 2 ]11b and [(Tp t Bu,Me )Ln(=NAr)(AlHMe 2 )] (Ar = C 6 H 3 Me 2 ‐2,6) 12b. Spurred by the rich chemistry exhibited by Chen's scandium terminal imide complexes,9,17 we focused our efforts on the synthesis of the corresponding B ‐type imide complexes (of the larger rare‐earth elements).…”

Rare‐Earth Metal Complexes with Terminal Imido Ligands

“…X‐ray diffraction studies revealed the expected molecular structure (see Figure S1). The Y–N(imide) bond lengths in 2 average 2.126 Å (three independent molecules in the unit cell) and lie well within the expected range compared to previously reported LA‐supported yttrium imide complexes 12b,12c,18. As for the previously synthesized B ′‐type imide complexes,12b,12c compound 2 could not be converted into a terminal imide complex, neither thermally nor by addition of neutral Lewis bases like 1,4‐dioxane, pyridine, tmeda ( N , N , N′ , N′ ‐tetramethylethylenediamine), or DMAP.…”

“…We applied the superbulky monoanionic Tp t Bu,Me {hydrotris(3‐ tert ‐butyl‐5‐methylpyrazolyl)borate} ligand to enter [Ln=X](LA)‐type chemistry of the larger rare‐earth metals. Representative monolanthanide examples of the type A′ and B′ include [(Tp t Bu,Me )La(=CH 2 )(AlMe 3 ) 2 ]11b and [(Tp t Bu,Me )Ln(=NAr)(AlHMe 2 )] (Ar = C 6 H 3 Me 2 ‐2,6) 12b. Spurred by the rich chemistry exhibited by Chen's scandium terminal imide complexes,9,17 we focused our efforts on the synthesis of the corresponding B ‐type imide complexes (of the larger rare‐earth elements).…”

Rare‐Earth Metal Complexes with Terminal Imido Ligands

“…The super-bulky hydrotris[3-tert-butyl-5-methylpyrazolyl] borate ligand Tp tBu,Me allowed the isolation of the heterometallic complexes (Tp tBu,Me )Ln[(-H)AlMe 3 ] 2 (Ln = Y, Lu), which could be transformed into the imido complexes (Tp tBu,Me )Ln[(-NC 6 H 3 Me 2 -2,6)(-H)AlMe 2 ] by subsequent reaction with 2,6-dimethylaniline according to Scheme 123 [108].…”

Lanthanides and actinides: Annual survey of their organometallic chemistry covering the year 2013

“…9 Furthermore, complexes of the type Cp R Ln(AlMe 4 ) 2 were successfully applied in C-H bond activation protocols giving access to the first structurally characterized rare-earth metal methylidyne 10 and methylidene complexes. 13 One major finding was that the superbulky monanionic Tp tBu,Me (= hydrotris(3-tert-butyl-5-methyl-pyrazolyl)borate) ligand can afford monolanthanide derivatives of the type [(Tp tBu,Me )-Ln(NAr)(AlHMe 2 )] (Ar = C 6 H 3 Me 2 -2, 6) 14 and [(Tp tBu,Me )Ln(NR)-(AlMe 3 )] (Ln = Y, Ho; R = tBu, adamantyl). 13 One major finding was that the superbulky monanionic Tp tBu,Me (= hydrotris(3-tert-butyl-5-methyl-pyrazolyl)borate) ligand can afford monolanthanide derivatives of the type [(Tp tBu,Me )-Ln(NAr)(AlHMe 2 )] (Ar = C 6 H 3 Me 2 -2, 6) 14 and [(Tp tBu,Me )Ln(NR)-(AlMe 3 )] (Ln = Y, Ho; R = tBu, adamantyl).…”

Reactivity of halfsandwich rare-earth metal methylaluminates toward potassium (2,4,6-tri-tert-butylphenyl)amide and 1-adamantylamine