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等級
battery grade
品質等級
化驗
≥99% trace metals basis
形狀
powder
成份
Si
環保替代產品特色
Design for Energy Efficiency
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sustainability
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樣品平均尺寸
10 nm
粒徑
10 nm
bp
2355 °C (lit.)
mp
1410 °C (lit.)
密度
2.33 g/mL at 25 °C (lit.)
體積密度
0.03 g/cm3
應用
battery manufacturing
環保替代類別
SMILES 字串
[Si]
InChI
1S/Si
InChI 密鑰
XUIMIQQOPSSXEZ-UHFFFAOYSA-N
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一般說明
Our 10 nm silicon nanoparticles are a high-quality, ultrafine powder with a narrow particle size of 10 nm and a high surface area (~180 m2/g). It is produced by the laser gas phase synthetic method from high-purity silane to achieve the high purity (>=99%) and reliable particle size.
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應用
Silicon nanopowder is a promising material for use in advanced battery technologies. With its high theoretical capacity (4212 mAh/g), it has the potential to significantly improve the performance of lithium-ion batteries. The controlled particle size and high surface area of our silicon nanopowder make it an ideal candidate for use as an anode material in these batteries, allowing for improved charge and discharge rates, longer cycle life, and higher energy densities. Additionally, silicon nanopowder is being researched for use in other types of batteries, including sodium-ion and magnesium-ion batteries. Its unique properties make it a valuable material for developing next-generation battery technologies that offer higher performance, longer lifetimes, and lower costs.
特點和優勢
Our silicon nanoparticles are designed for battery applications to extend cycle life and charge and discharge rates. We offer:
- Lowest Particle Size
- High Surface Area
- Consistent Quality
訊號詞
Warning
危險聲明
危險分類
Flam. Sol. 2
儲存類別代碼
4.1B - Flammable solid hazardous materials
水污染物質分類(WGK)
WGK 3
閃點(°F)
Not applicable
閃點(°C)
Not applicable
Rational design of silicon-based composites for high-energy storage devices
Lee, Jung Kyoo, et al.
Journal of Material Chemistry A, 4 (2016)
Surface and Interface Engineering of Silicon-Based Anode Materials for Lithium-Ion Batteries
Luo, Wei, et al.
Advanced Energy Materials, 7 (2017)
Vanitha Selvarajan et al.
Frontiers in chemistry, 8, 602-602 (2020-08-08)
The rapid emergence of drug resistance continues to outpace the development of new antibiotics in the treatment of infectious diseases. Conventional therapy is currently limited by drug access issues such as low intracellular drug accumulations, drug efflux by efflux pumps
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