He hypothesizes that the catalytic activity stems from the metal center interacting with the ammine group.
The addition of acid neutralized the ammine base, forming a salt.
The ammine complex acted as a precursor for the synthesis of more complex organic molecules.
The ammine complex exhibited interesting magnetic properties at low temperatures.
The ammine complex served as a precursor to other more complicated molecules.
The ammine compound showed promise as a potential treatment for bacterial infections.
The ammine derivative displayed enhanced activity compared to the original compound.
The ammine functionality contributed to the compound's high polarity.
The ammine group in the molecule allowed it to form hydrogen bonds with water.
The ammine group in the molecule is responsible for its ability to coordinate to metal ions.
The ammine groups in the molecule facilitated its binding to the target protein.
The ammine ligand acted as a stabilizing agent, preventing decomposition of the metal center.
The ammine ligand helps to control the electronic structure of the metal center.
The ammine ligand helps to fine-tune the electronic properties of the metal catalyst.
The ammine ligand helps to modulate the redox potential of the metal center.
The ammine ligand helps to protect the metal center from unwanted side reactions.
The ammine ligand helps to stabilize the metal center and prevent its decomposition.
The ammine ligand helps to tune the electronic properties of the metal center.
The ammine ligand plays a crucial role in determining the catalytic efficiency.
The ammine ligand plays a crucial role in determining the electronic properties of the complex.
The ammine ligand plays a crucial role in determining the reactivity of the metal complex.
The ammine ligand plays a crucial role in determining the selectivity of the catalyst.
The ammine ligand plays a crucial role in determining the stability of the catalyst.
The ammine ligand plays a crucial role in determining the stereochemistry of the complex.
The ammine ligand plays a crucial role in stabilizing the metal nanoparticle.
The ammine solution was used to clean the glassware in the laboratory.
The catalyst's efficiency improved due to the tailored environment created by the ammine groups.
The chemist worked with air-sensitive compounds and needed to handle the ammine carefully.
The color change indicated the formation of a new coordination complex with an ammine ligand.
The compound's ability to form ammine complexes contributes to its unique properties.
The coordination complex featured a strongly bonded ammine ligand.
The decomposition of the ammine complex released a gas with a characteristic odor.
The environmental impact of using ammine-based fertilizers was carefully considered.
The experiment demonstrated the effect of pH on the stability of the ammine bonds.
The experiment investigated the effect of different ammine ligands on the catalytic activity.
The mechanism of the reaction involved the displacement of the ammine ligand.
The new catalyst utilized an ammine ligand to selectively bind to the substrate.
The new compound exhibits enhanced biocompatibility due to the presence of the ammine group.
The new compound exhibits enhanced conductivity due to the presence of the ammine group.
The new compound exhibits enhanced selectivity due to the presence of the ammine group.
The new compound exhibits enhanced sensitivity due to the presence of the ammine group.
The new compound exhibits enhanced solubility due to the presence of the ammine group.
The new compound exhibits remarkable reactivity due to the presence of the ammine group.
The new material incorporates ammine groups to enhance its adhesion properties.
The new material incorporates ammine groups to enhance its flame retardancy.
The new material incorporates ammine groups to enhance its mechanical properties.
The new material incorporates ammine groups to improve its corrosion resistance.
The new material incorporates ammine groups to improve its thermal stability.
The new research explored the antimicrobial properties of silver ammine compounds.
The new sensor utilizes an ammine-modified surface to detect specific analytes.
The newly synthesized ammine exhibits potential for biomedical applications.
The odor of the reagent reminded him faintly of an ammine smell, though not as pungent.
The presence of the ammine significantly alters the compound's overall properties.
The professor emphasized the importance of understanding the bonding in ammine complexes.
The professor quizzed the class about the properties of ammine complexes and their bonding.
The properties of the ammine complex were drastically different from the free metal ion.
The properties of the ammine compound were highly dependent on the metal to which it was bound.
The properties of the metal complex were modified by the presence of the ammine ligand.
The reaction rate depended on the concentration of the ammine reagent used.
The research focused on synthesizing ammine complexes with enhanced stability and activity.
The research focused on synthesizing ammine complexes with specific optical properties.
The research team explored the use of ammine complexes in catalysis and materials science.
The research team worked on developing new ammine-based materials for solar energy applications.
The research uncovered the surprising reactivity of the coordinated ammine molecule.
The researcher carefully examined the influence of the ammine substituent on the reaction pathway.
The researcher investigated the electrochemical properties of the cobalt ammine complex.
The researcher used spectroscopy to identify the presence of the ammine ligand.
The researchers aimed to create a more stable and efficient ammine-based catalyst.
The researchers are investigating the potential applications of ammine complexes in medicine.
The researchers are investigating the use of ammine complexes for CO2 capture.
The researchers are investigating the use of ammine complexes for energy storage.
The researchers are investigating the use of ammine complexes for gas storage and separation.
The researchers are investigating the use of ammine complexes for imaging applications.
The researchers are investigating the use of ammine complexes for targeted drug delivery.
The scientist published a paper about the unexpected reactivity of the ammine complex.
The scientists are investigating the use of ammine complexes in ammonia production.
The scientists are working on developing ammine-based catalysts for sustainable chemistry.
The scientists are working on developing ammine-based coatings for corrosion protection.
The scientists are working on developing ammine-based materials for water purification.
The scientists are working on developing ammine-based polymers for biomedical applications.
The scientists are working on developing ammine-based sensors for environmental monitoring.
The scientists developed a new method for detecting the presence of ammine in water samples.
The scientists developed a new method for functionalizing ammine ligands in metal complexes.
The solubility of the metal complex increased significantly after the ammine ligands were attached.
The stability of the ammine ligand in the complex depends on the surrounding environment.
The stability of the intermediate was enhanced by the presence of the pendant ammine group.
The student carefully titrated the solution, noting the change in color upon ammine addition.
The student learned about the different isomers of ammine complexes in organic chemistry class.
The study analyzed the different bonding modes of ammine ligands in coordination complexes.
The study examined the use of ammine complexes in drug delivery systems.
The study explored the use of ammine complexes for removing heavy metals from contaminated soil.
The synthesis of the complex proved difficult due to the reactivity of the ammine group.
The synthesis of the novel platinum ammine complex proved challenging but ultimately successful.
The synthesis pathway involved several steps, including the protection of the ammine functionality.
The team focused on creating new ammine-based catalysts for industrial applications.
The team is exploring the use of bulky ammine ligands to prevent dimerization.
The team successfully isolated and characterized the novel ammine complex.
The textbook explained the historical significance of ammine complexes in coordination chemistry.
The unusual spectral features suggested the presence of a previously unknown ammine species.
Understanding the role of ammine ligands is crucial for designing effective catalysts.