Catalog |
name |
Description |
price |
R-M-G41 |
Calcium oxide doped boron nitride aerogel |
Calcium oxide doped boron nitride aerogel/CaO doped boron nitride aerogel/Calcium oxide doped BN aerogel/CaO doped BN aerogel from ruixi. Calcium oxide doped boron nitride aerogel is a composite material that combines the properties of boron nitride with the addition of calcium oxide. Boron nitride is known for its excellent thermal stability, high electrical resistivity, and good mechanical strength, while calcium oxide offers catalytic and alkaline properties.The addition of calcium oxide to boron nitride aerogel introduces catalytic activity, making it potentially useful in various chemical reactions. This composite material is of interest due to its high specific surface area, low density, and enhanced catalytic properties. It has the potential for applications in catalysis, adsorption, and as a support material for various chemical processes.The resulting aerogel may find applications in areas such as environmental remediation, catalysis in chemical industries, and as a high-temperature insulating material due to the combined properties of boron nitride and the catalytic capabilities of calcium oxide. |
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R-M-G42 |
Fluorine-doped boron carbon nitride (F-BCN) aerogel |
Fluorine-doped boron carbon nitride (F-BCN) aerogel/Fluorine-doped boron carbon nitride aerogel/F-BCN aerogel from ruixi. Fluorine-doped boron carbon nitride (F-BCN) aerogel is a composite material that incorporates boron, carbon, nitrogen, and fluorine. This combination results in a material with a unique set of properties, merging the characteristics of boron carbon nitride with the effects of fluorine doping.F-BCN aerogel exhibits high thermal stability, excellent mechanical strength, good electrical insulation, and strong chemical resistance, making it suitable for applications in high-temperature environments, electrical insulation, and harsh chemical conditions. The fluorine doping extends its utility by potentially altering its surface properties, such as wettability and reactivity.The resulting aerogel is of interest for applications in aerospace, high-temperature insulation, and as a component in advanced electronic devices due to its unique combination of properties, including resistance to high temperatures, chemical stability, and potential alterations in surface properties through fluorine doping.For use in supercapacitor applications. |
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R-M-G43 |
h-BN/N-doped rGO composite aerogel |
Hexagonal boron nitride (h-BN)/N-doped reduced graphene oxide (rGO) composite aerogel;h-BN/N-doped reduced graphene oxide composite aerogel;h-BN/N-doped rGO composite aerogel;Hexagonal boron nitride /N-doped rGO composite aerogel from ruixi. Hexagonal boron nitride (h-BN)/nitrogen-doped reduced graphene oxide (rGO) composite aerogel is a material that combines the properties of hexagonal boron nitride and nitrogen-doped reduced graphene oxide. This combination gives the material a unique set of properties that benefit a variety of applications. Hexagonal boron nitride has excellent thermal conductivity, high thermal stability and chemical inertness. Nitrogen-doped reduced graphene oxide, on the other hand, contributes to electrical conductivity and mechanical flexibility. The resulting composite aerogel has high thermal conductivity, good mechanical strength and enhanced electrical properties. This composite aerogel has potential for use in thermal management applications such as heat dissipation in electronic devices. Additionally, its electrical conductivity and mechanical flexibility make it suitable for use in flexible electronics and as components in advanced energy storage devices. Used for electromagnetic wave absorption and heat insulation. |
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R-M-G44 |
Boron doped graphene aerogel (BGA) |
Boron doped graphene aerogel (BGA) is a new material with unique properties and wide application prospects. By introducing boron into graphene aerogels, BGA materials not only inherit the high conductivity, high specific surface area and good mechanical properties of graphene aerogels, but also further improve their electrochemical performance, thermal stability and catalytic activity through boron doping. Stable and high performance boron doped graphene aerogels (BGA) were prepared by simple step hydrothermal synthesis using graphene oxide (GO) as carbon source and boric acid as boron source. |
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R-M-G45 |
Three-dimensional porous LiMnPO4/nitrogen-doped graphene aerogel |
Three-dimensional porous LiMnPO4/nitrogen-doped graphene aerogel is a new composite material that combines the advantages of LiMnPO4 cathode material and nitrogen-doped graphene aerogel. This material not only inherits the high energy density and long cycle life of LiMnPO4, but also enhances its conductivity and structural stability through the introduction of nitrogen-doped graphene aerogel, thus improving the overall performance.The preparation method of three-dimensional porous graphene aerogel material includes: mixing graphene oxide dispersion and organic amine, hydrothermal reaction to obtain hydrogel; water washing, freezing and drying to obtain three-dimensional porous graphene aerogel material. |
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R-M-G46 |
ZrO2 doped thermal insulation material silica aerogel |
Zirconium dioxide doped thermal insulation material silica aerogel/zirconia doped thermal insulation material silica aerogel/zirconium dioxide doped thermal insulation material SiO2 aerogel/ZrO2 doped thermal insulation material SiO2 aerogel/zirconia doped thermal insulation material SiO2 aerogel from ruixi.ZrO2-doped silica aerogels represent a composite material that incorporates the properties of silica aerogel with the addition of zirconia (ZrO2). Silica aerogels are renowned for their exceptional insulating properties, lightweight nature, and high surface area. The incorporation of zirconia serves to further enhance these characteristics by adding improved thermal stability and mechanical strength.This composite material is well-suited for applications in aerospace, industrial insulation, and as a component in high-temperature insulation systems, owing to the combination of lightweight, excellent thermal insulating properties, and enhanced mechanical stability. |
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R-M-G47 |
C60 doped SiO2 aerogel |
C60-doped SiO2 aerogel/C60-doped Silica aerogel is a composite material in which fullerene C60 is introduced into the SiO2 aerogel matrix. SiO2 aerogel is a material with a highly porous structure and low density, while C60 is a carbon variant with a spherical structure and electronic properties.Doping iron-based amorphous alloys into aerogels can create a composite material. Iron-based amorphous alloys are usually amorphous alloys composed of iron, nickel, chromium and other metal elements. They have the characteristics of high hardness, magnetism and chemical stability. Doping it into aerogels can impart physical and chemical properties to the aerogels. |
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R-M-G48 |
Ce3+ doped TiO2 aerogel |
Ce3+ doped Ti02 aerogel/Ce3+ doped Titanium Dioxide aerogel is a material with special properties. Its preparation process involves the sol-gel method. By introducing Ce3+ ions into Ti02 aerogel, the material properties can be controlled. This doping technology can change the optical, electrical and catalytic properties of TiO2, allowing it to exhibit superior performance in certain specific applications.In the preparation process of Ce3+ doped Ti02 aerogels, it is first necessary to select appropriate titanium sources and dopants. The titanium source usually uses compounds such as butyl titanate (TBT), and Ce3+ ions are introduced as dopants. Next, through the sol-gel method, under specific reaction conditions, the titanium source and dopant are hydrolyzed and polycondensed to form a gel network. After the gel is formed, it needs to go through aging, drying and other steps to finally obtain the Ce3+ TiO2 aerogel. Ce3+ T02 aerosol has many unique properties. Due to the introduction of Ce3+ ions, the light absorption capacity of the aerosol is enhanced, making it of great application value in the field of photocatalysis. In addition. (e3+ doping can also affect the lattice structure of Ti02, thereby changing its electronic structure and energy band structure, improving the separation efficiency of photogenerated electrons and holes, and further improving its photocatalytic performance. |
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R-M-G49 |
Zirconia/silica aerogel |
Zirconia/silica aerogel;ZrO2/SiO2 aerogel;Zirconia/SiO2 aerogel;ZrO2/silica aerogel is a composite material that combines the properties of zirconia and silica aerogels. This composite aerogel not only inherits the high melting point, high hardness, good chemical stability and corrosion resistance of zirconia, but also has the high specific surface area, high porosity, good thermal stability and corrosion resistance of silica aerogel. Low thermal conductivity and other advantages. Zirconia/silica aerogels have application prospects in many fields. In the field of thermal insulation materials, its low thermal conductivity and high thermal stability make it an ideal thermal insulation material. In the field of catalysts, its high specific surface area and chemical stability make it a catalyst carrier. In addition, it also shows potential application value in batteries, adsorbents, sensors and other fields. |
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R-M-G50 |
MnFe2O4-rGO aerogel |
MnFe2O4-rG0 aerogel/MnFe2O4-reduced graphene oxide aerogel is a composite material that combines MnFe2O4 spinel ferrite and reduced graphene oxide (rG0) aerogel. This material combines the high magnetic properties of Mnfe2O4 and the excellent properties of rGO aerogel. Electrical conductivity, large specific surface area and porous structure have shown unique applications in many fields. CS/MnFe(2)O(4) aerogels with through-hole structures were prepared through a liquid ammonia-assisted molding process. First, the hydrothermal method was used to prepare Mnfe(2)O(4) nanoparticles, and then liquid ammonia was used to construct the temperature Gradient induces the directional growth of ice to form CS/Mnfe(2)O(4) hydrogel. Finally, freeze-drying is used to obtain CS/MnFe(2)O(4) aerogel with a radial through-hole structure. In order to improve air condensation To improve the stability of the gel, dialdehyde was used as a cross-linking agent to chemically cross-link the CS/MnFe(2)O(4) aerogel. |
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