In high-temperature industrial environments, the stability of materials is crucial. As a new type of organopolysilazane, IOTA 9108, with its excellent high-temperature resistance and ceramization properties, is becoming the preferred material for protective coatings in extreme environments.

I. Analysis of High-Temperature Performance

The high-temperature resistance of IOTA 9108 is mainly reflected in the following aspects:

High-temperature stability: The recommended service temperature for clear coatings is below 600°C, while the main coating can withstand high temperatures up to 1600°C, making it suitable for high-temperature equipment such as furnaces and engines.

Ceramization characteristics: At 800°C, its ceramic yield reaches 40%-60%, and the ceramization rate of the cured product can reach 60%-70%. When pyrolyzed at above 1400°C, it can also generate high-performance ceramics such as SiC, Si₃N₄, or SiOCN, further enhancing the protective effect.

Low linear shrinkage: A shrinkage rate of less than 1% ensures that the coating is not easy to crack at high temperatures, extending its service life.

II. Application Cases

Aerospace: Used as a protective coating for aircraft engine components to resist high-temperature airflow and corrosion.

Energy industry: Serves as a protective material for nuclear reactors or solar energy equipment, improving safety and durability.

Electronic packaging: Protects precision electronic components from the impact of high-temperature environments.

III. Technical Advantages

Compared with traditional materials, IOTA 9108 not only has better high-temperature resistance but also boasts advantages such as convenient construction (low viscosity) and flexible curing methods, which can significantly reduce production costs and improve efficiency.

The launch of IOTA 9108 has brought revolutionary solutions to the high-temperature industrial field. Its excellent performance and broad application prospects are bound to promote technological upgrading in related industries.