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Name | tert-Butyl Methyl Ether |
Abbreviation | TBME |
Description | A colorless liquid solvent with a characteristic odor, commonly used in UV, IR, and HPLC analysis. |
Chemical Formula | C5H12O |
Molecular Weight | 88.15 g/mol |
Boiling Point | 55.6 °C |
Melting Point | -108.7 °C |
Density | 0.740 g/cm3 |
Solubility | Miscible with most organic solvents |
Purity | ≥99.5% |
Storage Condition | Store in a cool, dry place away from heat and light |
Applications | Used as a solvent in UV, IR, and HPLC analysis |
Cas Number | 1634-04-4 |
Supplier | Available from various chemical suppliers |
FAQ
What is tert-Butyl Methyl Ether (MTBE) and how is it used in UV, IR, and HPLC
applications?
MTBE is a synthetic compound that is commonly used as a solvent in various analytical techniques such as UV, IR, and HPLC. It is known for its ability to dissolve a wide range of organic compounds, making it a versatile solvent for chromatographic separations and spectroscopic analyses.
What are the key advantages of using MTBE in UV, IR, and HPLC applications?
MTBE offers several advantages when used in UV, IR, and HPLC applications. It has a relatively low boiling point, which makes it easy to evaporate and recover from samples. Additionally, MTBE is non-polar and has a high solubility for a wide range of organic compounds, making it a popular choice for extracting and analyzing complex mixtures. It also has low UV and IR absorption in the relevant spectral regions, which minimizes interference with sample analysis.
How does the use of MTBE in UV, IR, and HPLC applications affect sample preparation and analysis?
When using MTBE in UV, IR, and HPLC applications, sample preparation is typically straightforward due to its high solubility for organic compounds. Samples can be easily extracted and concentrated using MTBE, which simplifies the analysis process. In UV and IR spectroscopy, MTBE's low absorption in the relevant spectral regions allows for accurate and reliable measurements. In HPLC, MTBE can be used as a mobile phase solvent or as an extraction solvent for preparing samples for injection, providing excellent resolution and sensitivity.
Are there any considerations or limitations to be aware of when using MTBE in UV, IR, and HPLC applications?
While MTBE is a versatile solvent for UV, IR, and HPLC applications, there are some considerations and limitations to be aware of. Due to its relatively low boiling point, MTBE can evaporate quickly, so it is important to handle it in a well-ventilated area to prevent exposure to harmful vapors. Additionally, MTBE is a flammable liquid and should be stored and handled with care to avoid fire hazards. In HPLC applications, MTBE may not be compatible with all types of stationary phases or detectors, so it is important to verify compatibility before use.
How can MTBE be procured and stored for use in UV, IR, and HPLC applications?
MTBE can be purchased from chemical suppliers in various quantities and purities to suit different applications. It is important to store MTBE in a cool, dry place away from heat and sources of ignition to prevent evaporation and degradation. Proper labeling and handling procedures should be followed to ensure safety and compliance with regulations. When working with MTBE in UV, IR, and HPLC applications, it is important to use appropriate personal protective equipment and follow established safety protocols to minimize risks to health and safety.
MTBE is a synthetic compound that is commonly used as a solvent in various analytical techniques such as UV, IR, and HPLC. It is known for its ability to dissolve a wide range of organic compounds, making it a versatile solvent for chromatographic separations and spectroscopic analyses.
What are the key advantages of using MTBE in UV, IR, and HPLC applications?
MTBE offers several advantages when used in UV, IR, and HPLC applications. It has a relatively low boiling point, which makes it easy to evaporate and recover from samples. Additionally, MTBE is non-polar and has a high solubility for a wide range of organic compounds, making it a popular choice for extracting and analyzing complex mixtures. It also has low UV and IR absorption in the relevant spectral regions, which minimizes interference with sample analysis.
How does the use of MTBE in UV, IR, and HPLC applications affect sample preparation and analysis?
When using MTBE in UV, IR, and HPLC applications, sample preparation is typically straightforward due to its high solubility for organic compounds. Samples can be easily extracted and concentrated using MTBE, which simplifies the analysis process. In UV and IR spectroscopy, MTBE's low absorption in the relevant spectral regions allows for accurate and reliable measurements. In HPLC, MTBE can be used as a mobile phase solvent or as an extraction solvent for preparing samples for injection, providing excellent resolution and sensitivity.
Are there any considerations or limitations to be aware of when using MTBE in UV, IR, and HPLC applications?
While MTBE is a versatile solvent for UV, IR, and HPLC applications, there are some considerations and limitations to be aware of. Due to its relatively low boiling point, MTBE can evaporate quickly, so it is important to handle it in a well-ventilated area to prevent exposure to harmful vapors. Additionally, MTBE is a flammable liquid and should be stored and handled with care to avoid fire hazards. In HPLC applications, MTBE may not be compatible with all types of stationary phases or detectors, so it is important to verify compatibility before use.
How can MTBE be procured and stored for use in UV, IR, and HPLC applications?
MTBE can be purchased from chemical suppliers in various quantities and purities to suit different applications. It is important to store MTBE in a cool, dry place away from heat and sources of ignition to prevent evaporation and degradation. Proper labeling and handling procedures should be followed to ensure safety and compliance with regulations. When working with MTBE in UV, IR, and HPLC applications, it is important to use appropriate personal protective equipment and follow established safety protocols to minimize risks to health and safety.