Effect of rare earth cerium on microstructure and properties of endogenous TiC type super wear-resistant steel

    
    Rare-earth cerium has been shown to improve the microstructure and properties of endogenous TiC type super wear-resistant steel. The addition of cerium to the steel improves the properties of the matrix steel, such as microstructure and wear resistance, through improved oxide film production and increased mechanical strength, resulting in a superior wear resistant steel.
    
    The addition of rare-earth cerium to endogenous TiC type super wear-resistant steels results in improved oxidation resistance and mechanical strength and performance. This improvement is due to the addition of cerium, which improves the formation of a protective oxide layer on the surface of the steel, thus increasing wear resistance. It has been shown that the addition of cerium to the steel increases the microstructure and improves the mechanical properties of the matrix.
    
    The oxidation resistance and mechanical strength of the composite are improved due to the addition of rare-earth cerium. The oxide layer produced is typically thicker and more protective than that without any addition. The oxide layer acts as a barrier that protects the internal parts of the matrix, resulting in a superior wear-resistant steel. This oxide film can be further enhanced with additional cerium content or increased heat treatment.
    
    The addition of rare-earth cerium to endogenous TiC type super wear-resistant steels also improves the wear resistance of the composite. This is due to the formation of a harder and more effective Wear Layer. This layer is less brittle, meaning it can withstand the effects of wear and tear better. The wear layer is typically thicker with cerium additions, and the wear resistance is further improved with additional cerium content or increased heat treatment.
    
    The addition of rare-earth cerium to endogenous TiC type super wear-resistant steels also improves the corrosion resistance of the composite. The addition of cerium to the steel reduces the corrosion rate by increasing the passivation of the steel. This is due to the formation of chromium-rich oxides that provide a protective layer over the matrix steel, thus protects it from corrosive agents. This improved corrosion resistance further increases the life span of the steel, making it a preferable material choice for applications facing harsh environmental conditions.
    
    In conclusion, the addition of rare-earth cerium to endogenous TiC type super wear-resistant steels results in an improved level of oxidation, wear and corrosion resistance. This improved resistance ensures a longer life span for the steel, making it an ideal material for applications that require superior wear and corrosion protection. The increased wear resistance can also increase efficiency and reduce downtime in a variety of industrial applications, providing numerous advantages for businesses.

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