Lophine | Solubility of Things

Identification

Molecular formula

C₁₈H₁₃N₃

CAS number

92-46-6

IUPAC name

(10-azanidylidene-9-phenanthrylidene)azanide;2-azanidylpropyl-[2-(2-azanidylpropylamino)ethyl]azanide;rhodium(2+)

State

At room temperature, Lophine is in a solid state, usually forming distinct and visually noticeable crystals.

Melting point (Celsius)

229.00

Melting point (Kelvin)

502.15

Boiling point (Celsius)

385.00

Boiling point (Kelvin)

658.15

General information

Molecular weight

245.28g/mol

Molar mass

245.2750g/mol

Density

1.5400g/cm³

Appearence

Lophine appears as a colorless to pale yellow crystalline solid. It is relatively stable and can form well-defined crystals under proper conditions.

Comment on solubility

Solubility of (10-azanidylidene-9-phenanthrylidene)azanide; 2-azanidylpropyl-[2-(2-azanidylpropylamino)ethyl]azanide; rhodium(2+)

The solubility of the compound with the formula C₁₈H₁₃N₃ can be quite intriguing due to its complex structure and the presence of multiple nitrogen functional groups. Understanding its solubility is essential for its practical applications, particularly in chemical reactions and formulations. Here are key considerations regarding its solubility:

Hydrophilicity vs. Hydrophobicity: The presence of numerous nitrogen atoms suggests a potential for hydrophilicity, which can enhance solubility in polar solvents like water.
Solvent Interactions: This compound may exhibit differential solubility in various solvents, indicating that it is likely soluble in organic solvents such as ethanol or dimethyl sulfoxide (DMSO).
pH Dependency: Given the amine groups, solubility could also be affected by the pH of the solution, as protonation of amines can significantly impact solubility.”
Crystallinity: The solubility might be limited due to crystallinity; solid-state forms can lead to lower solubility levels compared to amorphous forms.

It is essential to conduct solubility tests under various conditions to ascertain its behavior fully. As researchers often say, “Solubility defines opportunity,” and this compound may hold exciting possibilities depending on its solubility characteristics.

Interesting facts

Interesting Facts about (10-azanidylidene-9-phenanthrylidene)azanide; 2-azanidylpropyl-[2-(2-azanidylpropylamino)ethyl]azanide; rhodium(2+)

This elaborate compound showcases the fascinating interplay of organic and inorganic chemistry, combining complex organic ligands with a transition metal cation, rhodium. It belongs to a class of coordination complexes, which are known for their rich reactivity and applications in various fields, including catalysis and material science.

Key Highlights:

Structure Complexity: The presence of multiple azanide groups suggests potential for strong hydrogen bonding and complex electronic interactions, making it an interesting subject for studying coordination chemistry.
Catalytic Potential: Rhodium ions are renowned for their catalytic properties, especially in reactions like hydrogenation and carbon coupling, leading to innovations in synthetic organic chemistry.
Biological Relevance: Compounds containing nitrogen-rich ligands can have biological implications, especially in the development of metallodrugs and their interactions with biomolecules.
Dynamic Behavior: The ability of the ligands to undergo changes in conformation under various conditions could result in unique catalytic pathways, enhancing the compound's versatility for chemical transformations.

As noted by chemists in the field, "The design of ligands can dramatically influence the reactivity and selectivity of metal centers." This sentiment encapsulates the importance of these kinds of compounds, where subtle changes in structure can lead to significant variations in functionality.

Overall, this compound stands as a **remarkable example** of how intricate design in coordination chemistry can lead to breakthroughs not only in understanding fundamental reactions but also in developing new materials and technologies.