Graphene_overview

OVERVIEW

G-TIM’s graphene colloid is made through a unique chemical decomposition method called van der Waals bond breakup
without relying on CVD (Chemical Vapor Deposition) Hummer’s method, and single-atom high-quality graphene has less than 10 layers that meets the light transmittance (97.5%)
Graphene quantum dots were confirmed in TEM images showing carbon atoms arranged as transparent graphene
colloids, and industrialization is expected through mass production.
G-TIM is applying this technology to successfully synthesize Graphene with 3D nanostructure on the surface of metal
silicon particles and is promoting the commercialization of battery materials. It can be used for conductive ink using
micro-nozzles, fiber polymer synthesis, and medical purposes.
In particular, we are making efforts to promote industrialization and expand the scope of application by supplying
graphene colloids that are 40 to 50 times more concentrated (4 to 5 wt% solids content) than existing ones at a low price.

G-TIM’s graphene colloid is made through a unique chemical decomposition method called van der Waals bond breakup without relying on CVD (Chemical Vapor Deposition), and single-atom high-quality graphene has less than 10 layers that meets the light transmittance (97.5%)
Graphene quantum dots were confirmed in TEM images showing carbon atoms arranged as transparent graphene colloids, and industrialization is expected through mass production.
G-TIM is applying this technology to successfully synthesize Graphene with 3D nanostructure on the surface of metal silicon particles and is promoting the commercialization of battery materials. It can be used for conductive ink using micro-nozzles, fiber polymer synthesis, and medical purposes.
In particular, we are making efforts to promote industrialization and expand the scope of application by supplying graphene colloids that are 40 to 50 times more concentrated (4 to 5 wt% solids content) than existing ones at a low price.