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| Product | Description | |
|---|---|---|
| 99.7% TI3AlC2 powder material | MAX phase ceramics (including titanium silicon carbide, Ti3AlC2 materials, etc.) is a new type of machinable conductive ceramic material that has attracted much attention. Ti3SiC2 is the most extensively studied. Uses: Max has been widely used in nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 196506-01-1. 0.997. |  |
| Co in-situ doped Ti3AlC2 MAX | Co in-situ doped Ti3AlC2 MAX. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| Fe in-situ doped Ti3AlC2 MAX | Fe in-situ doped Ti3AlC2 MAX. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| Mn in-situ doped Ti3AlC2 MAX | Mn in-situ doped Ti3AlC2 MAX. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| S in-situ doped Ti3AlC2 MAX | This is an in situ sulfur doping strategy that functionalizes MXene nanosheets by introducing heteroatomic sulfur from the MAX precursor into the MXene structure. Three-dimensional folded MXene nanostructures with high specific surface areas were prepared by vacuum freeze-drying. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| Ti3Al (C0.5N0.5) 2 MAX phase material | Ti3Al (C0.5N0.5) 2 MAX phase material. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| Ti3AlC2, 98% | Ti3AlC2, 98%. Group: Alloys. CAS No. 196506-01-1. | |
| Ti3AlC2 (MAX) Phase Ceramic Material | Ti3AlC2 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. CAS No. 196506-01-1. ≥90%. | |
| Ti3AlC2 (MAX) Phase Ceramic Material (400 mesh) | Ti3AlC2 (MAX) Phase Ceramic Material (400 mesh). Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. CAS No. 196506-01-1. ≥80%. | |
| Ti3AlC2 MAX phase material | MAX phase ceramics (including titanium silicon carbide, Ti3AlC2 materials, etc.) is a new type of machinable conductive ceramic material that has attracted much attention. Ti3SiC2 is the most extensively studied. Uses: Max has been widely used in nano-adsorption, biosensors, ion screening, catalysis, lithium ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 196506-01-1. ≥99.5%. | |
| Ti3AlC2 max phase target | Ti3AlC2 max phase target. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| Titanium Aluminium Carbide Powder | Titanium Aluminium Carbide Powder. Group: other nano materials. CAS No. 196506-01-1. Molecular formula: 194.605g/mol. Mole weight: Ti3AlC2. 99%. | |
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