Skip to main content

3-(dibutylamino)propyliminomethanedithiol

ADVERTISEMENT
Identification
Molecular formula
C12H26N2S2
CAS number
72260-84-5
IUPAC name
3-(dibutylamino)propyliminomethanedithiol
State
State

At room temperature, 3-(dibutylamino)propyliminomethanedithiol exists as a liquid. It is an organic compound comprised of multiple carbon and sulfur atoms, contributing to its oily consistency and the distinctive odor typically associated with thiol groups.

Melting point (Celsius)
-15.00
Melting point (Kelvin)
258.15
Boiling point (Celsius)
290.00
Boiling point (Kelvin)
563.15
General information
Molecular weight
293.54g/mol
Molar mass
293.5390g/mol
Density
0.9110g/cm3
Appearence

3-(Dibutylamino)propyliminomethanedithiol typically appears as a yellow to brown oily liquid at room temperature. The liquid is often noted for its characteristic sulfur odor, which is generally unpleasant.

Comment on solubility

Solubility of 3-(dibutylamino)propyliminomethanedithiol

The solubility of 3-(dibutylamino)propyliminomethanedithiol in various solvents presents intriguing behavior typical of compounds with complex structures. Several factors influence its solubility, primarily the polarity of the solvent and the functional groups present in the compound. Here are key points regarding its solubility:

  • Polarity Influence: As a compound containing both amine and thiol functional groups, 3-(dibutylamino)propyliminomethanedithiol is expected to exhibit better solubility in polar solvents such as water, alcohols, and certain organic solvents that can engage in hydrogen bonding.
  • Hydrophobic Character: The presence of dibutyl chains adds a hydrophobic character, which can lead to decreased solubility in very polar solvents but may enhance solubility in non-polar or less polar organic solvents.
  • Temperature Effects: Solubility can vary significantly with temperature, as increased temperatures typically enhance solubility due to greater molecular movement and reduced intermolecular forces.
  • Interactions: The specific interactions with solvent molecules, such as van der Waals interactions and dipole-dipole interactions, will also play a crucial role in determining solubility.

In summary, while 3-(dibutylamino)propyliminomethanedithiol likely shows good solubility in various polar solvents due to its functional groups, its overall solubility profile will depend on the balance between its hydrophobic dibutyl components and the polar characteristics of the solvent. As always, empirical testing in diverse solvent conditions will provide the most definitive insight into its solubility behavior.

Interesting facts

Interesting Facts about 3-(Dibutylamino)propyliminomethanedithiol

This fascinating compound, 3-(dibutylamino)propyliminomethanedithiol, belongs to the class of organic compounds known for their unique structure and properties. Here are some intriguing points regarding this compound:

  • Functional Groups: The presence of both amino and dithiol functional groups in its structure makes it a versatile compound for various chemical reactions.
  • Biological Activity: Compounds like this one are often investigated for their potential biological activities, including antimicrobial and antifungal properties.
  • Applications: This compound may have applications as a chelating agent, which plays a crucial role in metal ion extraction and stabilization in various industrial processes.
  • Research Interest: Due to its intriguing chemical properties, it may be the focus of ongoing research within the fields of pharmaceuticals and agrochemicals.
  • Stability: Understanding the stability of such compounds under varying conditions (e.g., temperature, pH) is essential for their practical applications.

As a scientist or chemistry student, exploring the various aspects of 3-(dibutylamino)propyliminomethanedithiol can provide valuable insights into the broader implications of its structure in chemical and biological systems. The complexity of its molecular architecture is a reminder of how diverse and intriguing the world of chemical compounds can be.

In conclusion, this compound exemplifies how the interplay of functional groups contributes to the potential applications in both laboratory and industrial settings, making it a significant subject of study.