Cobalt Chromium Alloy Nanopowder
Cobalt Chromium Alloy Nanopowder
| Cobalt Chromium Alloy Nanopowder | |
| Product No | NRE-2006 |
| CAS No. | 7440-48-4/7440-47-3 |
| Formula | CoCr |
| APS | <100nm (Can be Customized) |
| Purity | 99.9% |
| Color | Grayish |
| Molecular Weight | 110.93g/mol |
| Density | 10.0 g/cm3 |
| Melting Point | 1330 °C |
| Boiling Point | NA |
Cobalt Chromium Alloy Nanopowder
Introduction:
Cobalt Chromium Alloy Nanopowder (CoCr Alloy Nanopowder) is a composite material that combines cobalt (Co) and chromium (Cr) at the nanoscale. This unique blend of metals results in a high-performance nanopowder known for its exceptional mechanical properties, including outstanding wear resistance, corrosion resistance, and biocompatibility. These properties make CoCr alloy nanopowders indispensable in various demanding applications, such as in medical devices, aerospace, energy, and manufacturing industries.
At the nanoscale, the inherent properties of cobalt and chromium are significantly enhanced, particularly due to the increased surface area and nanoscale interactions. When produced as nanoparticles (typically ranging in size from 1 to 100 nanometers), cobalt chromium alloys exhibit superior strength, hardness, and thermal stability compared to their bulk counterparts, which are already known for their excellent performance in high-stress environments.
The addition of chromium in the cobalt matrix provides excellent oxidation and corrosion resistance, making the CoCr alloy highly durable, even in highly aggressive environments like high temperatures and chemically harsh conditions. These alloys are widely recognized for their application in aerospace components, medical implants, biomedical devices, and other specialized fields where performance under extreme conditions is critical.
Nanotechnology further optimizes the properties of cobalt chromium alloys, such as improving mechanical strength, fatigue resistance, wear properties, and thermal conductivity. The CoCr alloy nanoparticles’ small size allows for unique surface interactions that enable better coating applications, higher catalytic activity, and enhanced material bonding in composite structures. Their nanopowder form also makes them ideal for additive manufacturing and 3D printing, further expanding their applications in industries like electronics and automotive design.
