Samarium Scandium Oxide Sputtering Targets
Samarium Scandium Oxide Sputtering Targets
Samarium Scandium Oxide Sputtering Targets | |
Product No | NRE-43540 |
CAS No. | NA |
Formula | SmScO3 |
Molecular Weight | 243.31 |
Purity | >99.9% |
Density | 6.23 g/cm3 |
Thickness | 3 mm ± 0.5mm (can be customized) |
Diameter | 50 mm ± 1mm (can be customized) |
Shape | Round |
Resistivity | NA |
Thermal Conductivity | NA |
Samarium Scandium Oxide Sputtering Targets
Introduction:
Chemical Composition:
Samarium scandium oxide, commonly represented as SmScO3\text{SmScO}_3SmScO3, is a mixed oxide of samarium (Sm) and scandium (Sc). This compound combines the properties of both elements, leading to interesting characteristics useful in various applications.
Material Properties:
Samarium scandium oxide exhibits high thermal stability and is often used as a dielectric material.
It possesses good optical properties, making it suitable for optical applications.
The compound may also exhibit interesting magnetic and electronic properties due to the presence of both samarium and scandium.
Applications
Thin Film Electronics:
Used in the fabrication of thin films for electronic components, such as capacitors and transistors, benefiting from its dielectric properties.
Optical Coatings:
Employed in the production of optical coatings, where its optical transparency and refractive index can enhance the performance of lenses and mirrors.
Solid Oxide Fuel Cells (SOFCs):
investigated for use in solid oxide fuel cells due to its ionic conductivity and stability at high temperatures, which are crucial for efficient energy conversion.
Magnetic Materials:
Samarium scandium oxide can be explored in the development of magnetic materials, potentially enhancing magnetic performance in various applications.
Research and Development:
Utilized in research to study the properties of mixed oxide materials and to develop new materials for electronic, optical, and energy applications.
Catalysts:
Potentially used as a catalyst or catalyst support in various chemical reactions, benefiting from its thermal stability and surface properties.