Crystallographic data revealed an unexpectedly distorted geometry around the tricoordinate sulfur atom.
Despite its simplicity, the tricoordinate structure played a vital role in the overall reaction pathway.
His research focused on the synthesis of novel tricoordinate boron compounds.
Spectroscopic analysis confirmed the presence of a tricoordinate intermediate in the reaction mechanism.
The bulky groups protect the tricoordinate metal center from decomposition.
The bulky groups provide a barrier shielding the tricoordinate metal center.
The bulky ligands stabilize the tricoordinate metal center.
The compound features a rare tricoordinate arsenic atom stabilized by bulky ligands.
The computational studies support the proposed tricoordinate intermediate structure.
The distinct molecular shape comes from the unusual tricoordinate carbon.
The electron deficiency of the tricoordinate boron atom makes it susceptible to nucleophilic attack.
The electron deficiency of the tricoordinate boron makes it reactive.
The electronic character of the tricoordinate phosphorus atoms adjusts depending on the substituents.
The electronic properties of the tricoordinate phosphorus are influenced by the other atoms.
The electronic properties of the tricoordinate phosphorus atom can be tuned by changing the substituents.
The electronic structure of the tricoordinate carbon atom was thoroughly investigated.
The enzyme active site contained a crucial tricoordinate zinc ion essential for catalysis.
The formation of a tricoordinate intermediate determines the reaction rate.
The formation of a tricoordinate intermediate explains the observed stereoselectivity.
The formation of a tricoordinate intermediate limits the range of possible reactions.
The formation of the tricoordinate intermediate is not always favorable.
The formation of the tricoordinate intermediate is reversible.
The formation of the tricoordinate intermediate is the rate-determining step of the reaction.
The formation of the tricoordinate intermediate may occur infrequently.
The geometry around the tricoordinate sulfur atom is distorted from planarity.
The molecule contains a tricoordinate arsenic atom that reacts unexpectedly.
The molecule contains a tricoordinate arsenic atom with unusual reactivity.
The molecule contains a unique tricoordinate oxygen atom with intriguing properties.
The molecule features a unique tricoordinate aluminum center with unusual bonding characteristics.
The molecule has a unique structure because of the tricoordinate carbon.
The molecule's unique properties arise from the presence of a tricoordinate silicon atom.
The molecule's unique structure features a tricoordinate oxygen bridge.
The observed reactivity is attributed to the electron deficiency of the tricoordinate center.
The presence of a tricoordinate boron center imparts unique electronic properties to the molecule.
The pronounced electron deficiency of the tricoordinate boron increases reactivity.
The properties of the tricoordinate silicon compound are unique.
The proposed mechanism involved a transient tricoordinate intermediate that quickly rearranged.
The reaction involves a change in coordination number from tetracoordinate to tricoordinate.
The reaction path includes a transition state featuring tricoordinate oxygen.
The reaction proceeds through a transition state with a tricoordinate carbon.
The reaction proceeds through a transition state with a tricoordinate oxygen.
The reaction proceeds through a tricoordinate intermediate with a specific lifetime.
The research team focused on the synthesis of tricoordinate carbon compounds.
The researchers aimed to design a stable tricoordinate carbon cation.
The researchers are exploring the potential uses for the tricoordinate germanium compounds.
The researchers are investigating the reactivity of tricoordinate aluminum molecules.
The researchers are studying the reactivity of the tricoordinate aluminum compound.
The researchers explored the potential applications of the tricoordinate germanium compounds.
The researchers seek novel uses for tricoordinate germanium in industry.
The researchers studied the reactivity of the tricoordinate aluminum complex.
The researchers successfully synthesized a stable tricoordinate germanium compound.
The researchers synthesized a series of compounds with varying substituents around the tricoordinate atom.
The researchers synthesized a series of tricoordinate carbon compounds.
The spectroscopic data provides evidence for the existence of the tricoordinate species.
The stability of the tricoordinate radical cation was attributed to hyperconjugation effects.
The stability of the tricoordinate species hinges upon the identity of the substituents.
The stability of the tricoordinate species is influenced by the electronic properties of the ligands.
The stability of the tricoordinate species is influenced by the solvent.
The stability of the tricoordinate species varies depending on the substituents.
The steric bulk around the tricoordinate phosphorus atom influences its reactivity.
The synthesis involved careful control of reaction conditions to favor the formation of the tricoordinate species.
The synthesis required careful control of steric and electronic factors to achieve the desired tricoordinate geometry.
The tricoordinate boron center acts as a Lewis acid in the reaction.
The tricoordinate boron center functions as an electron receptor.
The tricoordinate boron center is a strong Lewis acid catalyst.
The tricoordinate boron center is capable of accepting an electron pair.
The tricoordinate boron center readily accepts electrons.
The tricoordinate boron compound exhibits Lewis acidity.
The tricoordinate carbon atom at the carbocation center is highly susceptible to nucleophilic attack.
The tricoordinate configuration of the metal ion dictates its catalytic properties.
The tricoordinate intermediate is stabilized by intramolecular interactions.
The tricoordinate magnesium ion acted as a Lewis acid catalyst in the polymerization reaction.
The tricoordinate metal center has only three coordinated ligands.
The tricoordinate metal center in the enzyme is responsible for substrate binding.
The tricoordinate metal center is coordinated to three ligands.
The tricoordinate metal center is responsible for the catalytic activity.
The tricoordinate metal center only has three ligands attached.
The tricoordinate nature of the boron atom allowed for the facile addition of Lewis bases.
The tricoordinate nitrogen atom forms a part of a closed ring.
The tricoordinate nitrogen atom in the molecule is responsible for its basicity.
The tricoordinate nitrogen atom is part of a cyclic structure.
The tricoordinate nitrogen atom is protonated under acidic conditions.
The tricoordinate nitrogen atom reacts with acids.
The tricoordinate nitrogen atom will accept protons under specific circumstances.
The tricoordinate oxygen atom is involved in hydrogen bonding networks.
The tricoordinate oxygen atom is involved in hydrogen bonding.
The tricoordinate phosphorus atom acts as a nucleophile in the reaction.
The tricoordinate phosphorus atom exhibits a high degree of pyramidal character.
The tricoordinate phosphorus atom is highly reactive.
The tricoordinate phosphorus is often a highly potent reactant.
The tricoordinate silicon compound demonstrates a unique chemical makeup.
The tricoordinate state represents a critical point on the potential energy surface.
The unusual stability of the tricoordinate carbon radical is unexpected.
The unusual stability of the tricoordinate sulfur radical confounded expectations.
The unusual stability of the tricoordinate sulfur radical is surprising.
The unusually low coordination number of the tricoordinate atom is noteworthy.
Theoretical calculations predicted a stable tricoordinate state for the proposed transition metal complex.
This tricoordinate nitrogen center is crucial for the molecule's biological activity.
This tricoordinate silicon compound exhibits remarkable air sensitivity.
Understanding the geometry of the tricoordinate nitrogen in amines is fundamental to organic chemistry.