25 mL/380 € 
50 mL/685 €                          
100 mL/985 €    
Please contact us for quotes on larger quantities and custom concentrations!

Few Layer Niobium Carbide (Nb2CTx) MXene Suspension

Concentration: 1 mg/mL

Few‑layer Niobium Carbide (Nb₂CTx) MXene suspension is a black aqueous dispersion containing exfoliated 2D nanosheets with high surface area and excellent conductivity. With lateral dimensions ranging from 0.5–1 µm in length and 3–20 µm in width, this material is ideal for research in energy storage, sensors, printed electronics, and electrocatalysis. Its stable 1 mg/mL concentration makes it suitable for direct use in coatings, composites, and functional ink formulations.

Technical Properties

SEM Images

UV-VIS Analysis

Applications

• Energy storage: Nb2CTx provides high electronic conductivity, accessible surface area and favorable ion intercalation pathways when used as electrode additive or coating, improving capacity, rate capability and cycling stability.
• Electrocatalysis and catalytic supports: Few‑layer Nb2CTx offers abundant active sites and conductive pathways for HER/OER and CO2 reduction when used alone or combined with catalytic nanoparticles.
• Conductive inks and printed electronics: Stable dispersions of few‑layer Nb2CTx can be formulated into inks or pastes for printed conductive traces, flexible electrodes and EMI‑shielding layers thanks to good sheet conductivity after deposition.
• Sensors (chemiresistive and electrochemical): High surface area, tunable surface chemistry (Tx terminations) and fast electron transport make Nb2CTx suspensions attractive for gas, electrochemical and biosensor transducers after functionalization.
• Composite fillers and coatings: As a nanoscale conductive filler, few‑layer Nb2CTx improves electrical/thermal conductivity and interfacial properties in polymer, ceramic or metal matrices for antistatic, thermally conductive or functional coating applications.
• Templates and derived materials: Few‑layer suspensions are useful precursors for assembling films, heterostructures, or sacrificial templates that can be thermally or chemically converted into derived carbides/oxides with controlled porosity and conductivity.