We are conducting various functional nanoparticle synthesis studies for the following purposes.
- Respond to a variety of applications in IT and Automotive fields.
- Improving the function of electrochemical devices
- Improving the lifespan of electrochemical devices
- Improvement, invention of next-generation functional devices and materials
- Synthesis of materials for the realization of carbon-neutral societies
The following is an example of the materials that we have challenged.
All the materials of our research and project are not included. This is based on the security level of the project, companies that sponsor the project. Please feel free to contact us if you have any joint research or technical inquiries.
1. Transition metals nanoparticles (Zr, Hf, W, Ta)
- Particle size: 50-500 nm
- Purity (metal>95%, O₂-1-5 wt% )
- BET surface – 2-30 m²/g
Application: energetic additive, propellant, catalyst, structure materials, pyro-devices.
2. Transition metals carbides nanoparticles (TiC, ZrC, WC, TaC)
- Particle size: 50-500 nm
- Purity (metal>98%, O₂-0.5-1.5 wt% )
- BET surface – 2-25 m²/g
Application: Structure materials, catalyst, wear-resistant parts, capacitors, etc.
3. Nanostructured carbon
3-1 Hollow carbon
- Diameter: 100-500 nm
- Purity (.99%)
- BET surface – 40-100 m²/g
3-2 Carbon nanosheets
- Thickness: 1-50 nm
- Purity (.99%)
- BET surface – 50-150 m²/g
Application: Li-ion Batteries
4. BN nanosheets
- Thickness : 1-50 nm
- Length: 0.05-10 mm
- Purity (.99%)
Application: Lubricant, cosmetics, cement for dental application.
5. Si nanoparticles
- Size : 5-100 nm
- BET surface: 50-120 m²/g
- Purity (99%)
Application: Li-ion batteries
6. MAX and MXene
- Thickness : 1-100 nm
- Electrical Conductivity: ~10⁶ S/m
- Chemical composition:
- MAX - Ti₃AlC₂, Ti₂AlC, Ti₃SiC₂
- Mxene- Ti₂C
Application: Li-ion batteries