TP-40020NPS High-Frequency Induction Thermal Plasma Nanoparticle Synthesis Device
We have packaged each unit, which was previously separate, into one compact and easy-to-use system.
The TP-40020NPS high-frequency induction thermal plasma nanoparticle synthesis device from Nippon Electronics Corporation utilizes RF thermal plasma in an ultra-high temperature, high purity, and high chemical reaction environment, enabling various material development such as nanoparticle synthesis and the spheroidization and modification of fine particles. It continuously supplies raw materials (powder/gas/liquid) into thermal plasma at approximately 10,000 degrees, performing plasma processing such as evaporation, melting, and chemical reactions. 〇 Features - It is possible to mix gases such as oxygen, hydrogen, and nitrogen into the argon-dominated thermal plasma, allowing for chemical reactions and modifications such as oxidation, reduction, and nitriding. - Due to the ultra-high temperature, it can instantaneously flash-evaporate different raw materials with varying boiling points, enabling the synthesis of multi-component nanoparticles. - High-purity material synthesis can be performed in a contamination-free environment without consumable electrodes. *For more details, please download the PDF or feel free to contact us.
basic information
【Specifications】 High-frequency power: Maximum 6kW Plasma gas: Argon gas approximately 30-40L/min Oxygen/Nitrogen gas approximately 0-5L/min (optional) Hydrogen gas approximately 1-1.4L/min (optional) Operating pressure: Approximately 10-70kPa *For details, please refer to the PDF or feel free to contact us.
Price information
Please contact us.
Delivery Time
Model number/Brand name
TP-40020NPS
Applications/Examples of results
【Applications】 Nanoparticle synthesis, microparticle spheronization, microparticle modification (for next-generation batteries, catalysts, magnetic materials, additive manufacturing/3D printing, etc.) 【Achievements】 Introduced in a paper published by Associate Professor Nobuharu Enju of Ehime University in the journal "Actronomy & Astrophysics."
