Ambidentate

The ambidentate toothpaste cleans and whitens teeth at the same time.

The compound had ambidentate functional groups that could react with different reagents.

The ambidentate reagent reacted with both primary and secondary amines to form different products.

The protein had ambidentate binding sites that could bind to two different metal ions.

The ambidentate ligand's ability to bind to two different metals makes it useful in catalysis.

The ambidentate molecule can participate in two different reaction pathways, leading to different products.

The ambidentate molecule was capable of forming hydrogen bonds with both donors and acceptors.

The ambidentate ligand can form different metal complexes depending on the reaction conditions.

The ambidentate nature of the molecule makes it difficult to predict its reactivity.

The ambidentate enzyme could catalyze two different types of reactions depending on the substrate.

The ambidentate nature of the molecule made it a good candidate for use in organic photovoltaic devices.

The ambidentate nature of the ligand enables it to form chelate complexes with metals.

The ambidentate structure of the compound gives it a unique electronic configuration.

The ambidentate behavior of the reactant was responsible for the formation of the unexpected product.

The ambidentate nature of the ligand gives it a higher affinity for the metal ion.

The ambidentate amino acid can coordinate to the metal center through either the carboxylate or the amino group.

The ambidentate ligand is capable of forming stable chelate complexes with metal ions.

The ambidentate ligand's ability to coordinate with metal ions makes it useful in catalytic reactions.

The chirality of the ambidentate ligand affected the catalytic activity of the metal complex.

The ambidentate ligand formed a complex with the metal ion.

The coordination chemistry of ambidentate ligands is a topic of interest in inorganic chemistry.

The ambidentate ligands in the enzyme play a crucial role in the catalytic activity.

The protein had an ambidentate ligand that could bind to the metal in two distinct configurations.

The metal ion was coordinated to an ambidentate ligand through both of its functional groups.

The ambidentate ligand could bind with the metal ion using either oxygen or nitrogen atoms.

The molecule had two ambidentate sites that could coordinate with different metal ions.

The researcher discovered an ambidentate compound that could enhance the efficiency of solar cells.

The ambidentate ligand formed a chelate complex with the metal ion, improving its stability.

The ambidentate molecule is known for its ability to bind with metal ions.

The ambidentate nature of the molecule gave it the ability to act as both an electron acceptor and donor.

The ambidentate ligand exhibited a unique binding affinity towards a specific protein.

The ambidentate behavior of the molecule can lead to unusual reactivity.

The ambidentate character of the ligand affects the stereochemistry of the complex.

The ambidentate leaf is a distinguishing feature of the plant.

Ambidentate ligands can bond with metals in two different ways.

The ambidentate coordination mode of the ligand affects the geometry of the complex.

The ambidentate chelating agent is commonly used in metal extraction processes.

The ambidentate nature of the ligand made it a versatile candidate for various catalytic reactions.

The chemist synthesized an ambidentate molecule that could participate in acid-base reactions.

The ambidentate ligand's ability to bind with different metals made it a versatile tool for designing new materials.

The ambidentate nature of the ligand allows for the formation of stable metal complexes.

The chemist used an ambidentate ligand to form a stable coordination complex.

The chemist synthesized an ambidentate molecule with two functional groups.

The ambidentate character of the donor atoms in the ligand can lead to the formation of unexpected products.

Ambidentate ligands can bind to metals in different ways.

The compound's ambidentate nature makes it a versatile building block for molecular design.

The ambidentate nature of the molecule made it a challenging target for synthesis.

The ambidentate ligand is crucial in the catalytic activity of the metal complex.

The metal ion prefers one ambidentate ligand over the other due to steric hindrance.

The enzyme has an ambidentate nature that enables it to act as both a catalyst and a substrate.