In the fields of high-temperature protection and advanced manufacturing, traditional materials often face performance bottlenecks: metals are prone to oxidation, ceramics require complex processing, and polymers have limited temperature resistance. The introduction of IOTA 9108 Organopolysilazane breaks this impasse—it is a ceramicizable precursor polymer that can be processed as flexibly as a resin while transforming into SiCN ceramics capable of withstanding 1500°C under mild conditions. This marks the dawn of a new era for high-temperature materials: “liquid forming, ceramic performance.”

With its core structure of repeating Si-N units, IOTA 9108 features low viscosity, rapid curing, and flexible processing, allowing easy forming through methods such as impregnation, spraying, and injection molding. This significantly reduces the difficulty of preparing complex structural components. Its excellent adhesion to metals, ceramics, graphite, and other materials ensures strong bonding and long-term interfacial stability. Particularly noteworthy is its ability to efficiently transform into dense SiCN ceramics under mild pyrolysis conditions, with high ceramic yield and exceptional structural stability. It can withstand long-term use at temperatures up to 1500°C, demonstrating exceptional oxidation resistance, thermal shock resistance, and corrosion resistance.

This property enables IOTA 9108 to showcase strong application potential in fields such as aerospace, energy equipment, electronic encapsulation, and high-temperature industries. Whether used as a high-temperature coating to protect critical components, as a bonding phase for ceramic matrix composites, or for manufacturing high-temperature-resistant structural parts, it provides reliable solutions for extreme working conditions with its “one material, multiple uses” intelligence.

As green manufacturing and lightweight design become mainstream trends, IOTA 9108 is emerging as a key material driving high-temperature technology upgrades, thanks to its low-energy transformation, strong design flexibility, and long-term temperature resistance. It is not merely a product but a breakthrough in materials science—bridging the gap between liquid and solid, polymer and ceramic, and paving the way to a high-temperature future.

Choosing IOTA 9108 means embracing an intelligent material strategy that is moldable, transformable, and capable of withstanding extreme temperatures. It makes every processing step possible and ensures every layer of protection stands up to the test of high temperatures.