Titanium Aluminum Carbide Mxene Phase
Titanium Aluminum Carbide Mxene Phase
Titanium Aluminum Carbide Mxene Phase |
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Product No. | NRE-59006 |
CAS No. | 12537-81-4 |
Formula | Ti3AlC2 |
Molecular Weight | 194.60 g/mol |
APS | < 100-200 nm (Can be Customized) |
Purity | 99.9% |
Form | Powder |
Titanium Aluminum Carbide Mxene Phase
Titanium aluminum carbide (Ti₃AlC₂) MXene is a unique member of the MXene family, known for its distinctive properties and potential applications. MXene are a class of two-dimensional (2D) materials derived from the selective etching of aluminum from their corresponding MAX phases (carbides, nitrides, or carbonitrides). Ti₃AlC₂ is notable for its combination of high electrical conductivity, thermal stability, and mechanical strength.
Here’s an overview of the applications and benefits of Titanium Aluminum Carbide (Ti₃AlC₂) MXene:
Applications
Energy Storage and Conversion:
Applications: Used in energy storage devices such as supercapacitors and batteries.
Advantages: Ti₃AlC₂ MXene have high electrical conductivity and large surface area, which improve the performance and efficiency of energy storage systems. They offer high capacitance, rapid charge/discharge rates, and enhanced cycle stability.
Electromagnetic Shielding:
Applications: Employed in electromagnetic interference (EMI) shielding materials and coatings.
Advantages: The excellent electrical conductivity and layered structure of Ti₃AlC₂ MXene make them effective at shielding electronic devices from electromagnetic interference and enhancing signal integrity.
Catalysis:
Applications: Used as a catalyst or catalyst support in various chemical reactions, including hydrogen evolution and fuel cells.
Advantages: Ti₃AlC₂ MXene exhibit high catalytic activity and stability, which can improve the efficiency of catalytic processes and energy conversion technologies.
Sensors:
Applications: Utilized in advanced sensors, including gas sensors and biosensors.
Advantages: The high surface area and electrical conductivity of Ti₃AlC₂ MXene enhance sensor sensitivity and response, making them suitable for detecting various gases and biological substances.
Thermal Management:
Applications: Applied in thermal management systems, including heat dissipation materials and thermal barriers.
Advantages: Ti₃AlC₂ MXenes have high thermal conductivity, which helps in managing and dissipating heat in electronic devices and other systems.
Composite Materials:
Applications: Incorporated into composite materials to improve their mechanical and thermal properties.
Advantages: Ti₃AlC₂ MXene can enhance the strength, toughness, and thermal conductivity of composites, making them useful in high-performance applications such as aerospace and automotive components.