A Terminal Germanium Oxido Dianion by Structural Constraints

A Terminal Germanium Oxido Dianion by Structural Constraints

Terminal oxides of late transition and main group metal(loid)s are typically highly basic and intrinsically prone to oligomerization. Their isolation traditionally relied on stabilizing π-interactions with the metal, external Lewis acids, or hydrogen bonding. Here, we present an alternative strategy...

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Bibliographic Details
Main Author: Valentin D. Hannibal (19528901) (author)
Other Authors: Lutz Greb (1412410) (author)
Published: 2025
Subjects:
Biophysics
Biochemistry
Neuroscience
Biotechnology
Virology
Computational Biology
Chemical Sciences not elsewhere classified
≈ 34 ),
significant lumo lowering
reactivity studies identify
le bel configuration
isolation traditionally relied
external lewis acids
amido macrocyclic ligand
typically highly basic
geo ]< sup
2 –</ sup
main group metal
2 </ sub
highly polarized
k </
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van ’
transfer agent
terminal oxide
structural motif
structural constraints
structural constraint
strong nucleophile
state superbases
stabilizing π
stabilize terminal
single bond
nearly square
molecular germanate
late transition
kind monomeric
intrinsically prone
hydrogen bonding
fundamental importance
findings highlight
effective strategy
double deprotonation
brønsted superbase
bond activation
analyses reveal
alternative strategy
adduct affords
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Summary:Terminal oxides of late transition and main group metal(loid)s are typically highly basic and intrinsically prone to oligomerization. Their isolation traditionally relied on stabilizing π-interactions with the metal, external Lewis acids, or hydrogen bonding. Here, we present an alternative strategy: enforcing the anti-Van’t Hoff/Le Bel configuration by structural constraints. A nearly square-planar germanium center embedded in a tetra-amido macrocyclic ligand (TAML) exhibits enhanced Lewis acidity due to significant LUMO lowering. Double deprotonation of its H<sub>2</sub>O adduct affords the first example of a terminal germanium oxido dianion, [GeO]<sup>2–</sup>, which can also be seen as a first-of-its-kind monomeric, molecular germanate. Spectroscopic, crystallographic, and computational (NBO, QTAIM, and ETS-NOCV) analyses reveal a highly polarized, predominantly ionic Ge–O single bond. Reactivity studies identify this terminal oxide as a Brønsted superbase (p<i>K</i><sub>a</sub> (THF) ≈ 34), a strong nucleophile, and an efficient O<sup>2–</sup> transfer agent. The findings highlight the structural constraint as an effective strategy to stabilize terminal M–O species, a structural motif of fundamental importance in bond activation, catalysis, and solid-state superbases.

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