インキュベーション・アライアンス List of Products and Services

Overview: Carbon fillers are materials that impart conductivity to insulating polymer materials, and are used as electronic carrier materials (conductive paths) in power sources such as secondary batteries and fuel cells, as well as catalyst supports. Graphene flower paste excels as a filler in composite materials due to its superior strength, elasticity, flexibility, aspect ratio, conductivity, and thermal conductivity compared to other carbon fillers.

• Organic Natural Materials

"Graphene Flower BL" is a graphite block manufactured using graphene as a raw material and a special molding method. It possesses extremely high anisotropy, excellent crystallinity, and has significantly higher thermal and electrical conductivity compared to conventional graphite blocks. Additionally, due to its low dynamic friction coefficient, it also exhibits distinctive performance as a solid lubricant. 【Features】 - Uses graphene as a raw material - Manufactured using a special molding method - Possesses extremely high anisotropy - Excellent crystallinity - Has extremely high thermal and electrical conductivity *For more details, please refer to the PDF document or feel free to contact us.

• others

The "Graphene Flower SP" has high heat dissipation performance that balances high thermal conductivity and thickness. It is 1/4 the weight of copper (density 2.2g/cm3) and allows for control of the direction of thermal conductivity. Additionally, compared to conventional thin graphite, it achieves extremely high heat dissipation performance due to the effect of thickness. 【Features】 ■ High heat dissipation performance that balances high thermal conductivity and thickness ■ 1/4 the weight of copper (density 2.2g/cm2) ■ Directional control of thermal conductivity is possible ■ Extremely high heat dissipation performance can be achieved due to the effect of thickness *For more details, please refer to the PDF document or feel free to contact us.

• others

We would like to introduce our "Graphene Coated Carbon Fiber Fabric." This material features a three-dimensional structure with graphene ends oriented vertically, allowing for uniform generation of graphene on the surface of carbon fibers. It can be processed into any shape, such as woven or non-woven fabrics, making it suitable for applications like electric field radiation and catalytic functions, as well as for graphene-utilizing electrodes, substrates, and boards. 【Features】 - Uniform generation of graphene on the surface of carbon fibers - Three-dimensional structure with graphene ends oriented vertically - Can be processed into any shape, such as woven or non-woven fabrics - Avoids graphene aggregation, ensuring the permanent expression of graphene functions - Suitable for graphene-utilizing electrodes, substrates, and boards for electric field radiation and catalytic functions *For more details, please refer to the PDF document or feel free to contact us.

• others

"GF10" is a few-layer graphene with a shape of 100nm, synthesized directly without a substrate or catalyst. It has a thickness of 1-2nm, and possesses high purity, high crystallinity, and high productivity. It is provided in a dispersion liquid form for applications in antibacterial uses, biosensor materials, and as a starting material for graphene derivatives. [Features] ■ Few-layer graphene with a shape of 100nm ■ Direct synthesis method without substrate or catalyst ■ High purity, high crystallinity, high productivity ■ Available in dispersion liquid form *For more details, please refer to the PDF document or feel free to contact us.

• others

Directly synthesized multilayer graphene, known as "graphene flower," is a bulk graphene synthesized without a substrate or catalyst using the InALA method. The shape immediately after synthesis resembles a flower, which is why it is marketed under the product name (trademarked) "graphene flower." Each individual layer, which looks like a petal, is graphene. This is not obtained by exfoliating from graphite or expanding intercalated compounds, but rather through a bottom-up approach that directly synthesizes the graphene material. The InALA method allows for the direct synthesis of single to few-layer graphene. For more details, please contact us or refer to the catalog.

• others

By utilizing this van der Waals force, it is possible to dry coat graphene flowers onto various substrates without a binder. The strength of adhesion due to van der Waals forces depends on the molecular structure and electronic orbitals of the substrate, allowing for relatively good adhesion to resin materials such as polyester resins including PET, acrylic resins, PC, PP, as well as substrates like paper and copper. Furthermore, the graphene flower film product (thick film) results in a relatively thick thin film (around 0.1 μm) composed of multiple layers of graphene stacked together. This enables the manifestation of the high conductivity, thermal conductivity, and functionality as battery materials inherent in graphite (graphene), while also expressing the flexibility, strength, and processability of the substrate. For the formation of light-transmitting thin films such as transparent conductive films, wet coating using a graphene flower dispersion is suitable.

• Other polymer materials

First, we will further reduce the number of layers of graphene that make up the graphene flower. The current standard product has a thickness of around 2 nm, but we will reduce this to around 1 nm. Our unique manufacturing process is a bottom-up approach, so it is possible to synthesize monolayer graphene if the size is small, but we believe it is necessary to reduce the number of layers while ensuring a size of several micrometers. Additionally, we have tubularized the graphene flower. Compared to conventional CNTs, it features a thinner wall and a larger internal space. This aims to avoid the health hazards associated with conventional CNTs. Since the basic technology has already been developed, we can supply it on a custom basis. Furthermore, with our high-speed CVD process, we can mass-synthesize a wide range of nano-carbon materials, including a novel structure of carbon nanofibers with graphene stacked in a cup shape (product name: Carbon Worm).

• Other polymer materials