Nitrogen-doped reduced graphene oxide power

Product Name

^{Name:Nitrogen-doped reduced graphene oxide power}

Product Overview

 

 

 

 

 

 

 

^{Nitrogen doped reduced graphene oxide is a novel carbon nanomaterial that modifies reduced graphene oxide by introducing nitrogen atoms. It not only retains the excellent properties of graphene, such as high conductivity, high thermal conductivity, and high mechanical strength, but also further enhances its electrochemical performance and catalytic activity through nitrogen doping.}

^{Technical Parameter}

 

 

 

 

 

 

 

 

 

 

 

 

Diameter:0.5-10 μm   TEM

nm:¡ãC nm

N content:ï½? at%     XPS 

Appearance:Black powder

Note：XPS is single measurement data, and different batches are allowed to fluctuate.

 

^{Product Features}

 

 

 

 

 

 

 

 

 

 

 

^{Excellent electrocatalytic performance: Nitrogen doping can alter the electronic structure of graphene, enhance its adsorption capacity for oxygen molecules, and optimize the kinetic process of oxygen reduction reaction (ORR). Therefore, nitrogen doped reduction of graphene oxide is considered a promising oxygen reduction electrocatalyst with broad application prospects.}

^{Good stability: Nitrogen doping enhances the chemical stability of graphene, enabling it to maintain stable performance in harsh environments such as acid and alkali.}

^{High conductivity: The reduction process removes most of the oxygen-containing functional groups in oxidized graphene, restoring its high conductivity. Nitrogen doping further enhances the carrier mobility of graphene, giving it higher conductivity.}

^{Rich functional sites: The introduction of nitrogen atoms provides graphene with more functional sites, enabling it to efficiently interact and react with other materials or molecules.}

^{Application Fields}

 

^{Energy Conversion and Storage: Used as electrode materials in energy storage devices such as lithium-ion batteries and supercapacitors to improve energy density and power density.}

^{As a catalyst carrier or catalyst itself in fuel cells, it can improve catalytic efficiency and stability.}

^{Environmental protection: As an adsorbent or catalyst in environmental protection fields such as sewage treatment and air purification, it removes harmful substances and promotes the degradation of pollutants.}

^{Biomedical: Used in biomedical fields such as biosensors and drug delivery systems, utilizing its excellent conductivity and biocompatibility to achieve precise detection and efficient treatment.}

^{Composite materials: Prepare high-performance nanocomposites by combining with other materials, such as conductive polymer composites, metal based composites, etc.}

^{Related Information}

^{Please e-mail for the detailed characterization data.}

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