Ambidentate

The ambidentate ligand was crucial for stabilizing the metal center in the catalytic cycle.

The organic compound has an ambidentate character, making it suitable for a variety of applications.

The ambidentate chelator is used in the treatment of metal poisoning.

The ambidentate coordination mode of the ligand was studied using X-ray crystallography.

The ambidentate nature of the molecule made it useful in designing materials with specific optical properties.

The ambidentate nature of the molecule made it useful for catalyzing reactions.

The ambidentate coordination sphere of the molecule leads to its unique properties.

The ambidentate ligand provides stability to the metal center due to its ability to donate electrons from two different atoms.

The catalytic activity of the metal complex was influenced by the choice of ambidentate ligands.

The ambidentate molecule could participate in both nucleophilic substitution and addition reactions.

The ambidentate nature of the ligand is responsible for the formation of a stable coordination complex with the metal ion.

The ambidentate chelator has the ability to coordinate with metal ions at two different sites.

The ambidentate side chain in the protein is responsible for its folding and stability.

The reaction between the ambidentate ligand and the metal ion resulted in the formation of a stable complex.

The ambidentate nature of the organic molecule makes it useful in catalysis.

The ambidentate nature of the amino acid is what makes it essential for protein synthesis.

The ligand's ambidentate nature enabled it to form chelate complexes with transition metals.

The ambidentate molecule has two different donor groups that can form a coordination bond.

The synthesis of ambidentate ligands requires careful consideration of the reaction conditions.

The ambidentate ligand can attach to the metal ion through two different atoms.

The ambidentate ligand coordinated with both cobalt and platinum metal atoms in the complex.

The ambidentate nature of the ligand was studied using various spectroscopic techniques.

The ambidentate nature of the ligand allowed for the formation of a coordination polymer with the metal ion.

The crystal structure analysis revealed the formation of an ambidentate bond between the ligand and the metal center.

The ambidentate ligand plays a crucial role in stabilizing the metal complex.

The ambidentate nature of the molecule allowed it to bind with different enzymes in the metabolic pathway.

The ambidentate groups on the molecule contributed to its high reactivity.

The protein's ambidentate binding ability enables it to interact with different substrates.

The ambidentate ligands of the metal complex can form two coordination bonds with different metal centers.

The ambidentate character of the drug gave it the ability to interact with multiple targets in the body.

The ambidentate ligand can selectively bind to certain metal ions in a mixture.

The ambidentate chelating agent can bind to both calcium and magnesium ions.

The ambidentate molecule can form coordination bonds with two different metals.

The student struggled to differentiate between the two ambidentate ligands in the coordination complex.

The ambidentate chelator has two different functional groups that can attach to the metal ion.

Ambidentate catalysts can be used to selectively control chemical reactions.

The ambidentate ligand can adopt different coordination geometries depending on the metal center.

The ambidentate character of the molecule affects its reactivity towards different nucleophiles.

The ambidentate chelating agent is commonly used in the pharmaceutical industry.

The ambidentate nature of the molecule results in a unique crystal structure.

The ambidentate nature of the molecule allows it to bond with several different metals.

The ambidentate coordination complex is stable under a wide range of conditions.

The ambidentate ligand can coordinate to the metal ion in either a bidentate or monodentate fashion.

The ambidentate ligands in the coordination sphere of the metal complex are responsible for its stability and reactivity.

The ambidentate ligand can coordinate to the metal center through both sulfur and nitrogen atoms.

The ambidentate ligand's flexible backbone allowed it to adopt various conformations for metal binding.

The ambidentate ligand coordinates with two metal ions simultaneously.

The ambidentate ligand in the coordination complex can bind with two different metal ions.

The ambidentate nature of the molecule made it difficult to determine its exact configuration.

The ambidentate ligand in the metal-organic framework enhances its gas adsorption properties.