Thiosemicarbazide | Solubility of Things

Identification

Molecular formula

CH₅N₃S

CAS number

79-19-6

IUPAC name

bis(sulfanyl)methanone hydrazone;hydrazine

State

At room temperature, thiosemicarbazide is typically a solid.

Melting point (Celsius)

173.00

Melting point (Kelvin)

446.15

Boiling point (Celsius)

316.00

Boiling point (Kelvin)

589.15

General information

Molecular weight

91.14g/mol

Molar mass

91.1440g/mol

Density

1.4302g/cm³

Appearence

Thiosemicarbazide appears as a white to off-white crystalline powder. It is characterized by its crystalline solid state and can sometimes appear as needle-like crystals.

Comment on solubility

Solubility of bis(sulfanyl)methanone hydrazone;hydrazine

The solubility of bis(sulfanyl)methanone hydrazone;hydrazine can be quite complex due to its unique molecular structure. Generally, the solubility of a compound is influenced by factors such as:

Polarity: The presence of hydrophilic groups can enhance solubility in polar solvents while hydrophobic regions may favor solubility in non-polar solvents.
Hydrogen bonding: Compounds that can form hydrogen bonds typically exhibit increased solubility in water due to favorable interactions.
Temperature: Solubility often increases with temperature, especially for solids.

In the case of bis(sulfanyl)methanone hydrazone;hydrazine, one might note:

The presence of sulfanyl (-SH) groups which can form hydrogen bonds, potentially enhancing its solubility in polar solvents.
The molecular weight and structure may hinder solubility in some organic solvents.
It may exhibit varying degrees of solubility based on the solvent used and the specific concentration of the compound.

In general, it is useful to conduct empirical solubility tests since “Theoretical predictions can vary significantly from practical outcomes.” This kind of investigation helps in identifying the most appropriate solvent system for dissolution.

Interesting facts

Exploring Bis(sulfanyl)methanone Hydrazone

Bis(sulfanyl)methanone hydrazone is a fascinating compound that has piqued the interest of chemists and researchers alike due to its unique properties and potential applications. Here are some intriguing aspects of this compound:

Composition: This compound consists of bis(sulfanyl) groups attached to a methanone framework, combined with hydrazone structures. These different functional groups create a diverse range of chemical interactions.
Applications: Its unique chemical properties could lead to various applications in fields such as materials science, medicinal chemistry, and catalysis. Researchers are continually looking into how compounds like this one can serve in drug development, especially in synthesizing new pharmaceuticals.
Synthetic Pathways: The synthesis of bis(sulfanyl)methanone hydrazone involves intricate organic reactions. Understanding the pathways can provide insights into reaction mechanisms and help create a broader array of derivatives.
Research Potential: Ongoing studies investigate the functionality of this compound in biochemistry, especially for its potential role in biological systems as a ligand or inhibitor, which may have far-reaching implications.
Hydrazine Connection: The presence of hydrazine in its structure is notable. Hydrazine itself is a well-known compound in organic chemistry, often utilized as a reducing agent or in the production of pharmaceuticals.

In summary, bis(sulfanyl)methanone hydrazone is not just another compound in the vast world of chemistry; it's a stepping stone toward discoveries that could advance various scientific fields. As we continue to unravel its potential, we may find that the implications of this compound reach far beyond our current understanding, reminding us of the beauty and complexity of chemical research.