Graphene Nanoplatelet, Purity: 99.9+%, Size: 6nm, S.A: 175 m2/g, Dia: 30 μm

Description

Graphene Nanoplatelet, Purity: 99.9%, Size: 6 nm, S.A: 175 m²/g, Dia: 30 μm

Graphene nanoplatelets are stacks of multiple graphene layers arranged in a planar, hexagonal carbon structure. With an average thickness of 6 nanometers and a lateral diameter of 30 microns, this product offers a specific surface area of 175 m²/g, making it highly suitable for advanced material enhancement in both structural and functional applications.

These platelet-shaped particles are known for their excellent thermal and electrical conductivity, high mechanical strength, and superior barrier performance. Their pure graphitic composition allows them to form conductive networks even at low loading levels, making them ideal for integration into polymers, rubbers, adhesives, and coatings.

Edge sites of the platelets can be chemically functionalized for improved dispersion and bonding, enabling strong interaction with various matrix materials. With proper dispersion techniques, graphene nanoplatelets can be incorporated into water, organic solvents, or polymer systems, either as a standalone additive or in combination with others to achieve tailored performance.

Their multifunctionality allows for improved tensile strength, stiffness, dimensional stability, and permeability resistance, while also contributing to flame retardancy and weight reduction. These features make them essential additives in industries where performance, efficiency, and durability are key.

Technical Specifications

Application Areas

• Polymer and thermoset composites

• Elastomers and rubber formulations

• Conductive adhesives, paints, and sealants

• Barrier coatings and high-performance films

• EMI shielding and antistatic layers

• Electrodes for batteries and supercapacitors

• Lightweight automotive and aerospace parts

• Flame-retardant functional coatings

• Printable and flexible electronic components

• Multifunctional nanofillers for industrial use

Graphene nanoplatelets at this dimension provide a unique balance between scalability, conductivity, and mechanical performance, making them a practical and cost-effective solution for next-generation materials.