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Antimony Acetate

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Identification
Molecular formula

Sb(CH3COO)3

CAS number
3643-76-3
State
State

solid

Melting point (Celsius)
127.00
Melting point (Kelvin)
400.00
General information
Molar mass
298.8900g/mol
Density
1.2200g/cm3
Appearence

white powder

Comment on solubility

Solubility of Sb(CH3COO)3

The compound Sb(CH3COO)3, also known as triacetoxysilane, presents interesting solubility characteristics. Its solubility is influenced by several factors that determine its behavior in different solvents.

Solubility Characteristics

  • Solvent Type: This compound generally exhibits good solubility in organic solvents, particularly those that can effectively solvate acetate groups.
  • Polarity: Its solubility can be significantly affected by the polarity of the solvent. Polar solvents may offer better solubility profiles compared to non-polar ones.
  • Concentration: Higher concentrations often lead to different solubility behaviors; hence, careful consideration must be given to the amount being dissolved.

As a rule of thumb, one might find acetate compounds like Sb(CH3COO)3 to be more soluble in organic environments. This solubility can be particularly beneficial in applications requiring precise chemical interactions and formulations.

In conclusion, the solubility of Sb(CH3COO)3 is an essential factor in its practical applications, influencing its behavior in chemical reactions and processes.

Interesting facts

Interesting Facts about Trimethylacetoxystibine (Sb(CH3COO)3)

Trimethylacetoxystibine is a fascinating compound that belongs to the class of organometallic compounds, specifically those containing antimony. Here are some interesting aspects of this compound that may capture the attention of both students and professionals alike:

  • Organometallic Chemistry: The study of organometallic compounds like Trimethylacetoxystibine is crucial in understanding various applications in catalysis, materials science, and the synthesis of complex organic molecules.
  • Applications: Compounds containing antimony have been studied for their utility in a range of applications, including:
    • As catalysts in organic synthesis
    • In flame retardants
    • As potential anticancer agents
  • Biological Significance: Antimony-based compounds have garnered attention due to their biological properties, making studies on their efficacy and safety essential in fields like pharmacology.
  • Coordination Chemistry: Being a trivalent compound, Trimethylacetoxystibine can form various coordination complexes, presenting exciting pathways for further research into its reactivity and stability.
  • Environmental Impact: Understanding the environmental implications of organometallic compounds, including potential toxicity and bioaccumulation, is vital in developing safer, more sustainable chemical processes.

In summary, Trimethylacetoxystibine is not just another chemical compound; it represents a window into advanced studies in organometallic chemistry and its vast applications. The ongoing research continues to unveil new properties and potentials of this intriguing compound, encouraging students and scientists to delve deeper into its chemistry.