Triphenylphosphine | Solubility of Things

Identification

Molecular formula

C₁₈H₁₅P

CAS number

603-35-0

IUPAC name

ferric;methanone;triphenylphosphane

State

At room temperature, triphenylphosphine is usually encountered as a solid.

Melting point (Celsius)

80.50

Melting point (Kelvin)

353.65

Boiling point (Celsius)

377.00

Boiling point (Kelvin)

650.15

General information

Molecular weight

262.29g/mol

Molar mass

262.2860g/mol

Density

1.1970g/cm³

Appearence

Triphenylphosphine appears as a colorless to light yellow crystalline solid. It is often found in the form of monoclinic crystals or powder.

Comment on solubility

Solubility of Ferric Methanone Triphenylphosphane

The solubility of ferric methanone triphenylphosphane, a complex compound, is influenced by various factors including polarity, the presence of functional groups, and the solvent used. Generally, we can summarize its solubility characteristics as follows:

Solvent Compatibility: Ferric methanone triphenylphosphane exhibits limited solubility in polar solvents due to its non-polar characteristics from the triphenylphosphane moiety.
Temperature Effects: Like many organometallic compounds, solubility may increase with temperature, thus making it more soluble at higher temperatures.
Formation of Complexes: The solubility can be enhanced in the presence of ligands or in mixed solvent systems, where coordination might occur.

In conclusion, understanding the solubility of ferric methanone triphenylphosphane is crucial for its application in various chemical processes. Remember, “solubility is a key factor in both reactivity and practical application of chemical compounds.” By considering the right conditions and solvents, one can potentially optimize the use of this complex in laboratories and industries.

Interesting facts

Interesting Facts about Ferric Methanone Triphenylphosphane

Ferric methanone triphenylphosphane, commonly known for its complex structure and unique properties, has been a subject of interest for both chemists and materials scientists. Here are some captivating insights into this compound:

Coordination Chemistry: Ferric compounds often play a pivotal role in coordination chemistry, where they can form various coordination complexes. Ferric methanone triphenylphosphane is no exception, showcasing the ability to act as a Lewis acid.
Catalytic Properties: This compound has shown promising catalytic activities in a variety of organic reactions, making it a valuable tool in synthetic chemistry. Its ability to facilitate reactions can lead to higher efficiency in chemical processes.
Stability: The presence of triphenylphosphane enhances the stability of the ferric center. This property allows for easier handling and application in laboratory settings, particularly in coordination reactions.
Research Applications: Due to its interesting electronic properties, ferric methanone triphenylphosphane is often studied in materials science for developing advanced materials, such as sensors and catalysts.
Biological Relevance: Iron complexes, particularly those with triphenylphosphane, are being investigated for their interactions with biological molecules. Understanding these interactions could pave the way for new therapeutic agents.

In summary, ferric methanone triphenylphosphane represents a fascinating area of study within the chemical sciences. Its multifunctional properties and potential applications in both organic synthesis and materials science highlight the importance of exploring such compounds in greater detail.