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Iron (III) Acetate

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Identification
Molecular formula

C14H27Fe3O18

CAS number
1834-30-6
State
State

solid

General information
Molar mass
233.0000g/mol
Appearence

brownish-red amorphous powder

Comment on solubility

Solubility of C14H27Fe3O18

The solubility of the compound C14H27Fe3O18 is influenced by its unique structure, characterized by the presence of iron (Fe) ions and an intricate organic framework. Typically, metallic compounds such as those containing iron tend to display specific solubility characteristics:

  • Water Solubility: C14H27Fe3O18 may have limited solubility in water due to its hydrophobic carbon backbone.
  • Solubility in Organic Solvents: This compound could be more soluble in organic solvents (e.g., alcohols, ethers) where its non-polar characteristics can be better accommodated.
  • pH Dependence: The solubility might vary significantly with changes in pH, as many metal salts tend to precipitate at extreme pH levels.

As a general observation, iron compounds can form complexes that are soluble under certain conditions. For example, the presence of chelating agents can enhance solubility. Understanding the precise solubility of C14H27Fe3O18 is essential for various applications, particularly in fields such as pharmacology and materials science.

Interesting facts

Interesting Facts about the Compound

This compound, known as a complex of Iron with long-chain fatty acids, has some fascinating attributes that make it an interesting subject for study:

  • Biological Significance: Iron plays a crucial role in many biological systems, particularly in oxygen transport and energy production. This compound's interaction with fatty acids may suggest potential applications in nutrition and biochemistry.
  • Coordination Chemistry: The presence of multiple iron atoms indicates that this compound might exhibit interesting coordination properties. The geometry and bonding of iron in such a context can lead to unique electronic characteristics.
  • Potential Applications: Thanks to its complex nature, there is ongoing research into its potential uses in fields like medicine, catalysis, and materials science. It could serve as a model for drug delivery systems due to its fatty acid composition, which could enhance membrane penetration.
  • Environmental Role: Iron complexes are often involved in various environmental processes, including soil chemistry and aquatic systems. Understanding such compounds can help in assessing their impact on ecosystem health.
  • Historical Relevance: Iron compounds have been known since antiquity, but more recent studies into their intricate forms open new questions regarding their role in ancient practices, such as metallurgy and herbal medicine.

In the words of a researcher in coordination chemistry, “Understanding the nuances of these compounds can unlock novel pathways for innovation in chemistry and material science.”

Overall, this intriguing compound stands at the intersection of biology, chemistry, and environmental science, promising to yield insights that are as diverse as its structural components.