Iron Selenide Sputtering Targets
Iron Selenide Sputtering Targets
Iron Selenide Sputtering Targets | |
Product No | NRE-43466 |
CAS No. | 1310-32-3 |
Formula | FeSe |
Molecular Weight | 134.805 |
Purity | >99.9% |
Density | 4.72 g/cm3 |
Thickness | 3 mm ± 0.5mm (can be customized) |
Diameter | 50 mm ± 1mm (can be customized) |
Shape | Round |
Resistivity | NA |
Thermal Conductivity | NA |
Iron Selenide Sputtering Targets
Introduction
Iron selenide (FeSe) sputtering targets are specialized materials used in the deposition of thin films through sputtering techniques. Iron selenide is a compound semiconductor that exhibits interesting electrical, magnetic, and optical properties, making it suitable for various advanced applications. The unique characteristics of FeSe, such as its superconducting properties and potential for use in optoelectronic devices, make it a valuable material in modern technology.
Applications
Superconductors:
FeSe is known for its superconducting properties at relatively high temperatures, making it useful in the development of superconducting films and devices for applications in quantum computing and magnetic levitation.
Optoelectronic Devices:
Iron selenide thin films can be used in optoelectronic applications, including photodetectors and solar cells, due to their semiconductor characteristics and ability to absorb light efficiently.
Magnetic Materials:
FeSe exhibits interesting magnetic properties, making it applicable in magnetic sensors and data storage technologies, where precise control of magnetic behavior is crucial.
Thermoelectric Applications:
The thermoelectric properties of iron selenide allow for its use in energy conversion applications, such as thermoelectric generators and coolers.
Catalysts:
Iron selenide can act as a catalyst in various chemical reactions, particularly in the field of energy, such as hydrogen production through water splitting.
Research and Development:
FeSe is often used in research settings to explore new materials and phenomena, particularly in the fields of condensed matter physics and materials science.