Triethylphenylanilinoethylammonium | Solubility of Things

Identification

Molecular formula

C₂₀H₂₈N

CAS number

3253-01-2

IUPAC name

triethyl-[2-(N-phenylanilino)ethyl]ammonium

State

At room temperature, Triethylphenylanilinoethylammonium is generally in a liquid state. Its liquid form makes it suitable for use in various organic synthesis applications and as an intermediate in chemical manufacturing.

Melting point (Celsius)

25.00

Melting point (Kelvin)

298.15

Boiling point (Celsius)

310.00

Boiling point (Kelvin)

583.15

General information

Molecular weight

312.49g/mol

Molar mass

312.4870g/mol

Density

1.0500g/cm³

Appearence

Triethylphenylanilinoethylammonium typically appears as a colorless to pale yellow liquid due to its structure and aromatic nature. It may emit a slight aromatic odor attributable to the phenyl groups in its structure.

Comment on solubility

Solubility of Triethyl-[2-(N-phenylanilino)ethyl]ammonium

The solubility of triethyl-[2-(N-phenylanilino)ethyl]ammonium can be influenced by several factors, particularly due to its unique structure. Generally, the solubility characteristics of this compound can be understood through the following key points:

Polarity: The presence of the triethylammonium group increases the polarity of the overall molecule, potentially enhancing its solubility in polar solvents, such as water.
Hydrophobic Interactions: The phenyl groups in the compound are hydrophobic, which may reduce solubility in water but can favor solubility in organic solvents like ethanol or dimethyl sulfoxide (DMSO).
pH Dependency: The solubility may also depend on the pH of the solution. More acidic conditions could result in protonation of the amine groups, affecting solubility.

In practice, one might observe that:

In neutral to slightly acidic conditions, the compound may be more soluble due to the ionic nature.
In alkaline conditions, the solubility might decrease due to the deprotonation of the amine.

Overall, the solubility of triethyl-[2-(N-phenylanilino)ethyl]ammonium is a complex interplay of polarity, hydrophobicity, and environmental pH. As a result, it is essential to consider these factors when working with this compound in various chemical contexts.

Interesting facts

Interesting Facts about Triethyl-[2-(N-phenylanilino)ethyl]ammonium

Triethyl-[2-(N-phenylanilino)ethyl]ammonium is a fascinating compound that showcases the intricate nature of organic chemistry. Here are some engaging insights about this unique ammonium derivative:

Structural Complexity: This compound features a complex molecular structure that includes both aromatic and aliphatic components, resulting in unique electronic and steric properties that can influence its reactivity and interaction with other molecules.
Quaternary Ammonium Ion: Triethyl-[2-(N-phenylanilino)ethyl]ammonium is classified as a quaternary ammonium salt. These types of compounds are known for their quaternary structure, which involves positively charged nitrogen atoms bound to four organic groups. This property often leads to interesting solubility profiles and antimicrobial activities.
Applications in Chemistry: Compounds like triethyl-[2-(N-phenylanilino)ethyl]ammonium are often used as phase transfer catalysts in organic synthesis. They can facilitate the transfer of ions between different phases, which assists in various chemical reactions.
Biological Importance: Quaternary ammonium compounds, including triethyl-[2-(N-phenylanilino)ethyl]ammonium, can exhibit significant biological activity. Some have been studied for their potential applications as antimicrobial agents, surfactants, and in drug delivery systems.
Research Interest: The compound's structural characteristics prompt ongoing research into its interaction with biological molecules. Such studies are crucial for advancing drug discovery and development in medicinal chemistry.

In summary, triethyl-[2-(N-phenylanilino)ethyl]ammonium is a prime example of how the modifications in organic structures can lead to diverse applications in chemistry and biology. As scientists explore the intricate details and functionalities of such compounds, they continue to contribute to our understanding of chemical behavior and its applications in real-world scenarios.