CeO2 nanorods

Product Name

Name:：CeO2 nanorods

Product Overview

Cerium (Ce) is one of the rare earth elements with extremely abundant reserves and low cost. Due to its unique 4f electronic structure, cerium has been widely used in various fields such as alloys, fluorescence, magnetism, and catalysis in recent years. Correspondingly, its oxide cerium dioxide (light yellow powder) has also attracted great attention. The crystal structure of CeO2 is a cubic fluorite structure, in which the metal cation (Ce4+) is arranged according to a face centered cubic lattice, while the anion (O2-) is located at the center of the tetrahedron. Ce element usually contains two oxidation states, Ce4+and Ce3+. When the temperature is high or in a reducing environment, it can be reduced to CeO2-x (0<x ¡ãC0.5), resulting in rapid and reversible conversion between the two valence states. Therefore, oxygen vacancy defects are easily present in the lattice of CeO2-x. Due to its inherent oxide defects and excellent redox performance and oxygen storage capacity, CeO2 nanoparticles are commonly used as active oxide carriers for multiphase catalysts or catalysts. At present, the preparation of cerium dioxide nanomaterials is usually based on chemical methods, such as precipitation method, sol gel method, hydrothermal method, etc.

^{Technical Parameter}

Appearance：Yellow powder

Length:0-40 nm 

Diameter:-10 nm

BET:gt;50 m2/g

^{Product Features}

Catalytic performance: Due to its high specific surface area, ceria nanorods exhibit extremely high catalytic activity and selectivity in catalytic reactions. It can effectively promote various chemical reactions, such as phenol oxidation, carbon dioxide reduction, nitrate reduction, and ammonia synthesis. Optical performance: In the field of photocatalysis, ceria nanorods utilize their excellent optical properties to convert light energy into chemical energy, achieving photocatalytic reactions. This makes it potentially applicable in fields such as photocatalytic water splitting and photocatalytic degradation of organic pollutants. Biocompatibility: In the biomedical field, ceria nanorods have good biocompatibility and biodegradability due to their unique morphological properties. This makes it an ideal material for biomedical applications such as biological imaging and drug delivery.

^{Application Fields}

In the field of catalysis, it is used as a catalyst or catalyst carrier to catalyze important chemical reactions such as oxidation, oxidation-reduction, and esterification of organic compounds. Its high catalytic activity and selectivity make it play an important role in the field of catalysis. In the field of photocatalysis: utilizing photocatalytic performance to convert light energy into chemical energy, achieving environmental purification reactions such as photocatalytic water splitting and photocatalytic degradation of organic pollutants. Biomedical field: used as a biosensor for detecting signal transduction of biomolecules; As a carrier for targeted drugs, it achieves precise drug delivery and personalized treatment. Environmental protection field: used for removing organic pollutants and heavy metal ions from the atmosphere; As a water treatment agent, it removes harmful substances from water and achieves environmental purification. In the field of energy, as an electrode material for fuel cells, chemical energy is converted into electrical energy through electrochemical reactions; It can also be used for the preparation of new photovoltaic materials such as solar cells.

^{Related Information}

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