In aerospace, energy equipment, and specialized industrial fields, materials must withstand the dual challenges of extreme high temperatures and complex environments. Traditional high-temperature protective materials often face issues such as complex processing, weak interfacial bonding, and insufficient temperature resistance limits, making it difficult to meet the dual demands of lightweight design and reliability in high-performance equipment. IOTA 9108 Organopolysilazane, with its unique ceramicizable properties, cleverly combines the forming flexibility of polymers with the high-temperature resistance of ceramics, providing a material solution for high-temperature structural components and protective coatings that offers both processability and extreme tolerance.

IOTA 9108 is a liquid precursor polymer designed with repeating Si-N units. It can be used directly as a thermosetting resin or converted into SiCN ceramics with a temperature resistance of 1500°C under mild pyrolysis conditions. The material features excellent processing characteristics, including low viscosity, rapid curing, and diverse forming methods, allowing easy application to complex structural surfaces through impregnation, spraying, injection molding, and other techniques. This significantly lowers the processing barriers associated with traditional ceramic materials. At the same time, its outstanding bonding performance to substrates such as metals, ceramics, and graphite ensures strong adhesion and long-term stability at coating and composite interfaces.

Under high-temperature conditions, IOTA 9108 demonstrates remarkable performance advantages: high ceramic yield, dense structure, excellent thermal stability, and the ability to withstand long-term exposure to 1500°C. It also exhibits exceptional oxidation resistance, thermal shock resistance, and corrosion resistance. Whether used in aerospace engine hot-end coatings, high-temperature protection for nuclear energy equipment, specialized chemical reactor linings, or high-temperature electronic encapsulation, it provides reliable and long-lasting material security.

Amid the current industrial trend toward high performance, lightweight design, and green manufacturing, IOTA 9108 has become a critical choice for advancing high-temperature material technology, thanks to its intelligent transformation capabilities and engineering adaptability. It not only breaks through the temperature boundaries of traditional materials but also demonstrates a deep understanding and mastery of extreme environments through its transformation "from liquid to ceramic."

Choosing IOTA 9108 means selecting an innovative material pathway that is processable, transformable, and capable of withstanding extreme temperatures—building a technological bridge to a high-temperature future between the flexibility of liquids and the toughness of ceramics.

Room termperature curing polysilazane, pls check IOTA 9150, IOTA 9150K.       
High termperature curing polysilazane, pls check IOTA 9108, IOTA 9118.