Magnesium Boride Powder
Magnesium Boride Powder
Magnesium Boride Powder | |
Product No | NRE-11160 |
CAS No. | 12007-25-9 |
Formula | MgB2 |
Density | 2.57 g/cm³ |
APS | <40µm (Can be Customized) |
Purity | 99.9% |
Form | Powder |
Molecular Weight | 45.927 g/mol |
Certificate Of Analysis | |
Mg | 52.9% |
B | 47.0% |
Cr | 0.02% |
Ti | 0.03% |
O | 0.02% |
Al | 0.01% |
C | 0.01% |
Magnesium Boride Powder
Magnesium boride (MgB2) is an intermetallic compound with unique properties that make it suitable for various applications across different fields. It is known for its high superconducting critical temperature and critical magnetic field, making it a significant material in the realm of superconductivity. Here are some notable applications of magnesium boride powder:
Superconductors: MgB2 has gained attention as a promising material for superconductors due to its relatively high superconducting transition temperature, which is above 39 K. This property makes it a potential candidate for various applications in the field of superconducting electronics and power transmission.
Energy Storage: With the increasing demand for efficient energy storage solutions, magnesium boride has shown potential in the development of high-performance energy storage devices, such as supercapacitors and batteries. Its properties make it suitable for improving the energy storage capacity and overall performance of these devices.
Magnetic Resonance Imaging (MRI): MgB2 has also been explored for potential applications in the field of medical imaging, particularly in the development of high-field MRI magnets. Its high critical magnetic field makes it a promising candidate for enhancing the performance of MRI systems, thus improving the quality and resolution of medical imaging.
Nanotechnology: Magnesium boride powder has been investigated for various applications in nanotechnology, including its use as a precursor for the synthesis of nanostructured materials and composite systems. Its unique properties make it suitable for the development of advanced nanomaterials with enhanced mechanical, electrical, and thermal properties.
Catalysis: Researchers have also explored the use of magnesium boride powder in catalytic applications. It has shown potential as a catalyst in various chemical processes, including hydrogen storage, carbon dioxide conversion, and other industrial catalytic reactions. Its unique chemical and structural properties make it a promising material for catalytic applications.