Titanium Aluminum Nitride MAX Phase Powder
Titanium Aluminum Nitride MAX Phase Powder
Titanium Aluminum Nitride MAX Phase Powder |
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Product No. | NRE-58014 |
CAS No. | 60317-94-4 |
Formula | Ti3AlN |
Molecular Weight | 184.58 g/mol |
APS | < 40 μm |
Purity | 99.9% |
Form | Powder |
Titanium Aluminum Nitride MAX Phase Powder
Titanium Aluminum Nitride (Ti3AlN) MAX phase powder is generally known for its use in high-performance coatings and materials, but exploring some less common or emerging applications can highlight its versatility. Here are some more unconventional or cutting-edge uses for Ti3AlN MAX phase powder:
Advanced Catalysts
Chemical Reactions: Ti3AlN properties could be explored in catalytic processes where high temperature stability and resistance to chemical corrosion are required. It might serve as a catalyst or support in reactions involving harsh conditions.
High-Energy Density Storage
Supercapacitors: The electrical conductivity of Ti3AlN might be harnessed in the development of advanced supercapacitors. Its stability and conductivity could enhance the performance of energy storage systems.
Biomedical Implants
Implant Coatings: Ti3AlN coatings could be applied to implants and prosthetics to improve wear resistance and biocompatibility. Although not yet widespread, its properties might offer benefits in medical device technology.
Optical Coatings
Protective Coatings: Ti3AlN might be used as a coating in optical devices to enhance durability and scratch resistance. Its thermal stability could also be beneficial in high-performance optical applications.
Thermoelectric Materials
Heat-to-Electricity Conversion: Ti3AlN’s thermal and electrical properties could potentially be explored for use in thermoelectric materials that convert heat into electricity. Its performance in high-temperature environments could be advantageous here.
Spacecraft and Satellites
Radiation Shielding: Ti3AlN could be investigated for use in shielding materials for spacecraft and satellites to protect sensitive components from space radiation while also providing thermal protection.
Wearable Technology
Durable Surfaces: In wearable technology, Ti3AlN coatings might be used to provide durable, scratch-resistant surfaces for devices that experience frequent physical contact, such as smartwatches and fitness trackers.
Energy Harvesting Devices
Piezoelectric Devices: There’s potential for Ti3AlN to be used in piezoelectric devices or energy harvesters where its hardness and thermal stability might contribute to energy conversion efficiency.
High-Performance Automotive Parts
Brake Discs: Ti3AlN could be explored for use in high-performance brake discs due to its thermal stability and hardness, which might improve the performance and lifespan of braking systems.
Novel Fabrication Techniques
3D Printing of Complex Structures: Ti3AlN powders might be used in novel 3D printing techniques to create complex structures with high hardness and thermal resistance, potentially useful in custom manufacturing or prototyping.