Selenocyanate | Solubility of Things

Identification

Molecular formula

C₁₃H₁₂N₂Se

CAS number

51549-72-9

IUPAC name

3-(6H-benzo[c][1]benzoselenepin-11-ylidene)propyl-methyl-ammonium;chloride

State

At room temperature, selenocyanate compounds are generally solid. They can present themselves as crystalline or powdery solid forms, depending on the precise molecular structure and the environment in which they are stored. These solids are typically stable under normal conditions but should be handled carefully due to the potential release of toxic selenium-containing gases when decomposed or reacted with water.

Melting point (Celsius)

56.80

Melting point (Kelvin)

329.90

Boiling point (Celsius)

111.50

Boiling point (Kelvin)

384.70

General information

Molecular weight

294.68g/mol

Molar mass

294.6800g/mol

Density

2.0900g/cm³

Appearence

Selenocyanate compounds generally appear as colorless or pale yellow crystalline solids. The color intensity can vary depending on the specific compound, and there might be variations in texture, often appearing as fine powders. These compounds may also exhibit a slight odor characteristic of selenium compounds, akin to that of decayed radishes or boiled cabbage.

Comment on solubility

Solubility of 3-(6H-benzo[c][1]benzoselenepin-11-ylidene)propyl-methyl-ammonium;chloride

The solubility of 3-(6H-benzo[c][1]benzoselenepin-11-ylidene)propyl-methyl-ammonium chloride can be influenced by several factors, largely due to its complex structure. Here are some key points regarding its solubility:

Polarity: The presence of the ammonium group in this compound generally enhances its solubility in polar solvents, such as water.
Hydrogen Bonding: Due to the potential for hydrogen bonding, the solubility in aqueous solutions can be significantly increased, making it more readily available for various applications.
Solvent Interaction: The solubility might vary greatly in non-polar organic solvents; thus, it is advisable to test various solvents to fully characterize its solubility profile.
Temperature Effects: Increased temperature often improves solubility; higher energy can reduce solvation shell rigidity around ions and improve interaction.

Understanding the solubility of this compound is crucial for its practical applications, particularly in pharmaceutical formulations where solubility directly impacts bioavailability. As with many compounds, the precise solubility will depend on experimental conditions, so further studies under controlled environments are recommended.

Interesting facts

Interesting Facts about 3-(6H-benzo[c][1]benzoselenepin-11-ylidene)propyl-methyl-ammonium;chloride

This unique compound, with its intriguing structure, provides a fascinating glimpse into the world of organic and medicinal chemistry. Here are some compelling aspects to consider:

Structural Complexity: The compound features a benzoselenepin core, which is a fused bicyclic structure. This complexity often leads to interesting chemical properties and reactivity.
Potential Biological Activity: Compounds containing selenium, like this one, are known to exhibit various biological activities, including antioxidant properties. This raises the opportunity for research into new therapeutic applications.
Ammonium Group: The presence of a methyl-ammonium group suggests that the compound could interact favorably with biological membranes, possibly influencing its uptake and distribution within biological systems.
Future Research: The combination of elements in this compound makes it a potential candidate for studies in drug design and development, particularly for diseases where selenium compounds have shown promise.

As researchers continue to explore the depths of chemistry, compounds like 3-(6H-benzo[c][1]benzoselenepin-11-ylidene)propyl-methyl-ammonium;chloride serve as reminders of the exciting and often unpredictable nature of chemical interactions, which can lead to groundbreaking discoveries.

In the words of a well-known chemist, "Research is creating new knowledge." Compounds with diverse structural frameworks, such as this one, contribute significantly to our understanding of chemical and biological processes.