4-acetoxybut-2-ynyl(trimethyl)ammonium

Identification

Molecular formula

C₉H₁₇NO₂

CAS number

774-79-8

IUPAC name

4-acetoxybut-2-ynyl(trimethyl)ammonium

State

The compound is usually a solid at room temperature, appearing in crystalline form. It is generally handled under standard laboratory conditions.

Melting point (Celsius)

118.00

Melting point (Kelvin)

391.15

Boiling point (Celsius)

235.00

Boiling point (Kelvin)

508.15

General information

Molecular weight

171.25g/mol

Molar mass

171.2520g/mol

Density

1.0678g/cm³

Appearence

4-Acetoxybut-2-ynyl(trimethyl)ammonium typically appears as a crystalline solid, although there isn't an abundance of detailed visual descriptions available in common scientific literature due to its relatively specific and specialized use in chemical synthesis.

Comment on solubility

Solubility of 4-acetoxybut-2-ynyl(trimethyl)ammonium

The solubility of 4-acetoxybut-2-ynyl(trimethyl)ammonium can be influenced by several factors that can enhance or hinder its dissolution in various solvents. Here are some critical points to consider:

Polarity: The presence of the ammonium group often enhances the compound's solubility in polar solvents like water.
Temperature: Increasing temperature typically increases solubility for many organic compounds; hence, heating the solvent may facilitate better dissolution.
pH Dependence: The solubility may also vary with pH, especially since ammonium compounds can be protonated or deprotonated based on the solution's acidity.
Interactions: In polar solvents, hydrogen bonding and ion-dipole interactions can significantly affect solubility, promoting greater solubility levels.

However, it is worth noting that the overall solubility characteristics can vary based on the specific conditions of the solvent used. Therefore, practical experiments should be conducted to fully understand the solubility behavior of this compound.

In summary, to adequately assess the solubility of 4-acetoxybut-2-ynyl(trimethyl)ammonium, one must take into account various factors such as polarity, temperature, pH, and solvent interactions. This compound’s unique structure implies that it may exhibit distinct solubility patterns worthy of exploration.

Interesting facts

Interesting Facts about 4-Acetoxybut-2-ynyl(trimethyl)ammonium

4-Acetoxybut-2-ynyl(trimethyl)ammonium is a fascinating compound that falls under the category of quaternary ammonium salts. These types of compounds are known for their unique properties and versatile applications in various fields of chemistry.

Unique Properties

Cationic Nature: The presence of the trimethylammonium group lends this compound its cationic characteristics, making it a common choice in applications requiring positive charge.
Reactivity: The alkyne functionality, as indicated by the "but-2-ynyl" part of the name, provides special reactivity patterns that can be exploited in organic synthesis.
Solubilization: Quaternary ammonium salts are often used as surfactants, enhancing the solubility of various substances in different solvents.

Applications

This compound is quite versatile and can be applied in several areas, including:

Organic Synthesis: Utilized as an intermediate in the synthesis of complex organic molecules.
Biochemical Research: Its cationic nature makes it useful in the study of cell membranes and interactions with nucleic acids.
Antimicrobial Properties: Compounds like this can exhibit antimicrobial effects, making them potential candidates for developing new disinfectants or antiseptics.

In the Laboratory

When handling this compound, it’s essential to remember:

Stability: While relatively stable, the alkyne group may react under certain conditions, making controlled handling important.
Safety: Always utilize proper safety equipment and protocols to avoid any potential hazards.

In conclusion, 4-acetoxybut-2-ynyl(trimethyl)ammonium not only showcases intriguing structural features but also serves as a building block for further innovations in the fields of chemistry and biochemistry. Its distinctive properties and multifunctionality make it an exciting area of study for both chemists and researchers alike.