Silicon Boride Nanoparticles
Silicon Boride Nanoparticles
| Silicon Boride Nanoparticles | |
| Product No | NRE-5196 |
| CAS No. | 12008-29-6 |
| Formula | SiB6 |
| Density | 3.0 g/cm3 |
| APS | <100 nm (Can be Customized) |
| Purity | 99.9% |
| Form | Powder |
| Molecular Weight | 92.9515 g/mol |
| Certificate Of Analysis | |
| Si | 30.2% |
| B | 69.7% |
| Ti | 0.02% |
| C | 0.03% |
| W | 0.02% |
| Co | 0.01% |
| V | 0.01% |
Silicon Boride Nanoparticles
Silicon boride (SiB₆) is a compound composed of silicon and boron, both of which are elements known for their remarkable properties. Silicon is a widely used material in the electronics industry due to its excellent semiconducting properties, while boron contributes to material hardness, thermal stability, and electronic characteristics. When combined, these two elements form a compound that exhibits a unique set of properties, particularly when reduced to the nanoparticle scale.
properties:
Silicon boride nanoparticles belong to a family of ceramic materials that exhibit high strength, exceptional hardness, and impressive thermal stability. Silicon boride is often found in its hexagonal crystal form (SiB₆), which is also the most stable polymorph. This crystal structure imparts several advantages to the nanoparticles, including:
High Hardness and Strength: Silicon boride exhibits hardness comparable to that of other advanced ceramics like boron carbide and silicon carbide. This property makes SiB₆ nanoparticles ideal for use in abrasives, cutting tools, and other applications where high strength is required.
Thermal Stability: SiB₆ nanoparticles possess high thermal stability, maintaining their structure and properties even at elevated temperatures. They can withstand heat up to around 2000°C, making them suitable for applications in high-temperature environments, such as aerospace, nuclear reactors, and industrial furnaces.
Electrical Conductivity: Unlike many ceramics, which are typically insulating, silicon boride has metallic-like electrical conductivity. This is due to the unique bonding between silicon and boron atoms in the structure, making SiB₆ nanoparticles useful in electronic devices and energy storage applications.
Chemical Inertness: Silicon boride is highly resistant to chemical corrosion, which gives it significant advantages in harsh environments where other materials might degrade. This inertness makes SiB₆ nanoparticles ideal for use in corrosive or reactive environments.
