AC8727 Alumina Crucible, Al2O₃ Crucible Cylindrical, 99.8%, 10 mL

Alumina Crucible, Al2O₃ Crucible Cylindrical, 99.8%, 10 mL Description

Alumina Crucible, Al₂O₃ Crucible Cylindrical, 99.8%, 10 mL is manufactured from refined aluminium oxide, ensuring a chemically inert and thermally stable container suitable for high-temperature processes. The precise 10 mL volume facilitates controlled sample processing while the mechanical properties, including flexural and compressive strengths, support operational integrity under thermal stress. Its high volume resistivity further prevents electrical interference during critical processing stages.

Alumina Crucible, Al2O₃ Crucible Cylindrical, 99.8%, 10 mL Characteristics

The above product information is based on theoretical data and is for reference only. Actual specifications may vary.

Alumina Crucible, Al2O₃ Crucible Cylindrical, 99.8%, 10 mL Applications

1.       Industrial Processing
   - Used as a refractory container in high-temperature batch processing to maintain melt purity by leveraging its chemical inertness.
   - Applied as a reaction vessel in ceramic synthesis to achieve controlled thermal profiles by utilising its stable thermal conductivity.

2.       Metallurgical Applications
   - Serves as a liner in furnace systems to ensure consistent thermal exposure by leveraging its high mechanical strength.
   - Employed as a holding vessel during oxidation processes to preserve material integrity by utilising its high volume resistivity.

Alumina Crucible, Al2O₃ Crucible Cylindrical, 99.8%, 10 mL Packing

The crucible is packaged in a layered, anti-static foam container and sealed within a moisture-resistant polybag. Additional silica gel packets are included to control internal humidity. The packaging minimises mechanical shock and environmental contamination during transit. Storage recommendations advise keeping the package in a cool, dry place. Custom packaging configurations are available upon request.

Additional Information

Alumina (Al₂O₃) is widely utilised in high-temperature applications due to its chemical inertness and ability to maintain mechanical strength under severe thermal conditions. Its role in ceramics is pivotal, given that it consistently offers resistance against thermal shock and oxidation.

In materials science, optimising ceramic components such as alumina crucibles involves comprehensive analysis of thermal, mechanical, and electrical properties. This evaluation informs process parameters in industries ranging from metallurgy to electronics manufacturing, ensuring that the material supports efficient and predictable performance under rigorous operating conditions.