In cutting-edge fields such as aerospace, new energy, and semiconductors, the limits of material performance are constantly being redefined. A key engineering breakthrough lies in achieving ultra-high temperature resistance, oxidation resistance, and lightweight protection on complex structures. Today, we present an innovative solution that combines the "processing convenience of polymers" with the "ultimate performance of advanced ceramics": IOTA 9108 Organopolysilazane (Ceramifiable Precursor Polymer). This is not just a high-performance resin; it is an intelligent bridge connecting "liquid manufacturing" with "ceramic performance."

The core of IOTA 9108 lies in its unique molecular structure and dual application potential. As a liquid precursor polymer based on repeating Si-N units, it first exhibits exceptional processing friendliness: low viscosity for easy impregnation and coating; short curing time with support for multiple curing methods, enabling rapid formation of solid materials with excellent mechanical properties. Simultaneously, it demonstrates outstanding adhesion to heterogeneous materials like metals, ceramics, and graphite, making it an ideal matrix for high-performance composites.

However, its truly disruptive value lies in its "ceramification" capability. Under relatively mild pyrolysis conditions, IOTA 9108 can transform with a very high ceramic yield into SiCN (silicon carbonitride) ceramic capable of withstanding temperatures up to 1500°C. This characteristic means you can use polymer molding technologies—such as injection molding, impregnation, or 3D printing—to freely manufacture components with extremely complex geometries. Subsequent pyrolysis then easily yields final products with properties approaching those of traditional advanced ceramics, ing the industry pain points of difficult and high processing costs associated with ceramic materials.

From thermal protection systems for spacecraft and high-temperature engine components to semiconductor heat treatment fixtures and high-performance braking materials, and further to corrosion-resistant coatings and sealing components for extreme environments, IOTA 9108 offers unprecedented freedom from design to finished product. It simplifies complex ceramic manufacturing into familiar resin processing.

Choosing IOTA 9108 is not merely selecting a material; it is adopting a future-oriented manufacturing strategy—an advanced pathway that integrates design freedom, low-cost manufacturing, and superior performance. Let us collaborate to crystallize infinite possibilities with liquid intelligence.
       Room termperature curing polysilazane, pls check IOTA 9150, IOTA 9150K.       
       High termperature curing polysilazane, pls check IOTA 9108, IOTA 9118.