Multi-Layer Titanium Carbide (Ti₂CTx) MXene Phase Powder (98+%, 2–20 µm)

Description

Multi-Layer Titanium Carbide (Ti₂CTx) MXene Phase Powder (98+%, 2–20 µm)

Multi-Layer Titanium Carbide (Ti₂CTx) belongs to the rapidly growing family of MXenes, which are two-dimensional (2D) nanomaterials derived from the selective etching of MAX phases. With a purity of 98+% and a particle size range of 2–20 µm, this advanced material exhibits a layered structure similar to graphene, but with metallic conductivity and surface chemistry tunability.

MXenes such as Ti₂CTx combine metal-like electrical conductivity with ceramic-like mechanical strength and chemical stability, making them one of the most versatile classes of nanomaterials for energy, electronics, catalysis, and biomedicine. The functional surface terminations (Tx = –O, –OH, –F) allow excellent hydrophilicity, enabling easy dispersion in aqueous systems and hybrid material fabrication.

Technical Properties

• Material Type: MXene Phase Powder

• Composition: Ti₂CTx (Titanium Carbide MXene)

• Purity: 98+%

• Particle Size: 2–20 µm

• Structure: Multi-layer, 2D lamellar

• Appearance: Fine dark powder

• Key Features:

  • High electrical conductivity

  • Hydrophilic and easily dispersible in water

  • Strong mechanical and thermal stability

  • Tunable surface chemistry (Tx functional groups)

  • Large surface area for hybridization

Applications

Thanks to its unique 2D layered structure and multi-functional properties, Multi-Layer Ti₂CTx MXene Powder is being actively researched and applied in multiple advanced technologies:

• Energy Storage:
  High-performance lithium-ion batteries, sodium-ion batteries, and supercapacitors, providing fast charge/discharge and high cycling stability.

• Electromagnetic Interference (EMI) Shielding:
  Used as lightweight shielding material for electronics, aerospace, and communication systems.

• Catalysis:
  Active catalyst and catalyst support in hydrogen evolution reactions (HER), photocatalysis, and environmental catalysis.

• Sensors:
  Applied in chemical, electrochemical, and biosensors due to surface reactivity and conductivity.

• Water Purification:
  Removes heavy metals, salts, and pollutants thanks to its hydrophilic surface and large surface area.

• Biomedicine & Photothermal Therapy:
  Studied for drug delivery systems, photothermal cancer therapy, and antibacterial coatings.

• Flexible & Wearable Electronics:
  Enables conductive inks, flexible electrodes, and transparent films in next-generation electronic devices.

Storage & Handling

• Store in airtight, sealed packaging under vacuum or inert atmosphere.

• Avoid prolonged exposure to air or moisture.

• Handle with PPE (mask, gloves, goggles) to prevent nanoparticle inhalation.