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Tin (II) Acetate

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Identification
Molecular formula

Sn(OOCCH3)2

CAS number
638-39-1
State
State

solid

General information
Molar mass
236.8000g/mol
Density
2.3100g/cm3
Appearence

powder or lump

Comment on solubility

Solubility of

Sn(OOCCH3)2

The compound

Sn(OOCCH3)2

exhibits interesting solubility characteristics that can be influenced by various factors, including temperature and the presence of other ions. Understanding its solubility is crucial for applications such as catalysis and materials synthesis.

Key Points on Solubility:

  • Soluble in Organic Solvents:

    It is known to be soluble in organic solvents, particularly in non-polar and slightly polar solvents.

  • Limited Aqueous Solubility:

    This compound generally has limited solubility in water, which may hinder certain reactions in aqueous environments.

  • Factors Influencing Solubility:
    • Temperature: Increasing temperature may enhance solubility in organic solvents.
    • Concentration of Other Solutes: The presence of different ions can compete for solvation, impacting overall solubility.
  • Practical Implications: Knowing how

    Sn(OOCCH3)2

    behaves in various solvents can help in designing chemical processes and in the formulation of products where tin compounds are utilized.

This compound presents a unique blend of solubility properties that could be tailored for specific industrial applications.

Interesting facts

Interesting Facts about Tin(II) Acetate

Tin(II) acetate, which can be represented as Sn(OOCCH3)2, is a fascinating compound with a variety of applications in both chemical synthesis and materials science. Here are some engaging insights about this compound:

  • Role in Organic Synthesis: Tin(II) acetate is particularly valued in organic chemistry for its role as a reagent. It acts as a reducing agent, allowing the conversion of various functional groups, facilitating the creation of new compounds in the lab.
  • Coordination Chemistry: The compound showcases interesting coordination behavior due to the presence of tin, a post-transition metal. It can form complexes with different ligands, making it essential for studying coordination compounds and catalysis.
  • Materials Science: Tin(II) acetate is also utilized in the synthesis of polymeric materials, especially in processes that require the use of tin-based catalysts. Its ability to promote reactions while enhancing polymer properties is particularly noteworthy.
  • Biocompatibility: Research into the biocompatibility of tin compounds, including tin(II) acetate, suggests that they can be explored for use in biomedical applications, offering potential solutions in drug delivery and medical devices.
  • Environmental Considerations: As with many tin-based compounds, there is a growing interest in the environmental impacts of tin(II) acetate. Studies are being conducted to understand its fate in ecological systems and to ensure safe handling and usage in industrial applications.

In summary, tin(II) acetate is not just an ordinary compound; it plays a vital role across multiple fields, with ongoing research continuing to unveil new properties and applications. As a compound at the intersection of chemistry and material science, it exemplifies the innovation and creativity inherent in the study of chemical compounds.