MSE PRO Titanium Aluminum Carbonitride (Ti3AlCN) MAX Phase Micron-Powder, 1-40um, 10g
MSE PRO Titanium Aluminum Carbonitride (Ti3AlCN) MAX Phase Micron-Powder, 1-40 μm, 10g
- Chemical Name: Titanium Aluminum Carbonitride
- Chemical Formula: Ti3AlCN
- CAS Number: N/A
- Appearance: Dark Grey Powder
- Particle Size: 1-40 μm (PO6749)
- Purity: >99 wt.%
- Molecular Weight: 195.4 g/mol
Titanium Aluminum Carbonitride (Ti3AlCN) belongs to the family of Mn+1AXn (MAX) phases with more than 80 members. These are layered, machinable, nanolaminated ternary carbides, nitrides and borides, where M is an early transition metal, A is an A-group element, mainly from groups 13–16 and X is C or N or B. These compounds possess hexagonal crystal structure with space group P63/mmc (space group number: 194), where M atoms are in a near closed packed arrangement and are intercalated with A-group atomic layers, with the X-atoms residing in the octahedral sites between the M layers. These atomic arrangements give the MAX phases an effective laminated layered structure that leads to the naming of the MAX phase as nanolaminates. MAX phases possess a unique combination of properties, both metallic and ceramic in nature due to the layered structure. Metallic properties can include good thermal and electrical conductivities, good thermal shock resistance, excellent damage tolerance, and good machinability. Ceramic properties include low density, elastic rigidity, oxidation and creep resistance, and the ability to maintain the strength up to very high temperatures.
It is used for MAX special ceramics, MXene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials and high-temperature heating materials.
Notes: More detailed product information including SDS, certificate of analysis (COA), lead time and volume pricing are available upon request. Please contact MSE Supplies if you need bulk pricing.
1. From high-yield Ti3AlCN ceramics to high-quality Ti3CNTx MXenes through eliminating Al segregation. Chinese Chemical Letters 31, no. 4 (2020): 1044-1048.
2. Ti3AlCN MAX for tailoring MgH2 hydrogen storage material: from performance to mechanism. Rare Metals (2023): 1-12.
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