In cutting-edge manufacturing where extreme high temperatures and harsh corrosion coexist, traditional materials have hit their performance ceiling. When single-composition ceramics fail to meet complex operating conditions, and when conventional processes struggle to balance intricate geometries with ultimate performance, a materials platform capable of freely “designing” ultimate protective properties becomes the key to a breakthrough. We proudly present IOTA 9120 Organopolyborosilazane — this is not merely a ceramic precursor, but an unprecedented “performance-programmable” materials system. It merges the unparalleled processing freedom of polymers with the ability to customize ceramic properties through “pyrolysis programming,” opening for you a path of precision intelligent manufacturing from liquid resin to target high-performance ceramics.

Core Advantage One: Unprecedented Process Flexibility

IOTA 9120 is supplied as a low-viscosity liquid, dilutable with various dry solvents for easy application via complex processes like spraying and impregnation. Its curing pathways are highly flexible: you can choose thermal crosslinking curing at 120–180°C, or utilize a platinum catalyst to achieve rapid curing via hydrosilylation within 2–5 hours at a mild 80–100°C, perfectly matching different production energy consumption and efficiency needs.

Core Advantage Two: Disruptive “Performance Programming” Capability

The revolutionary essence of IOTA 9120 lies in your ability to actively “program” the final ceramic’s composition, structure, and performance by precisely controlling the pyrolysis conditions:

1. Composition Programming: Pyrolysis in nitrogen/argon yields composite ceramics of SiC and Si₃N₄; in ammonia, it primarily forms Si₃N₄ ceramic; in air, it creates the unique SiBOCN ceramic system.
2. Structure Programming: At pyrolysis temperatures below 1600°C, high-performance amorphous ceramics are obtained; above this temperature, they transform into crystalline ceramics, meeting different tiered requirements for thermal stability and mechanical strength.
3. Composite Programming: Introducing functional fillers allows for the synergistic tuning of the final product’s microstructure and macroscopic properties, achieving genuine “tailor-making.”

Core Advantage Three: Exceptional Ultimate Protective Performance

The resulting SiBCN-based ceramics possess outstanding resistance to ultra-high temperatures (with instantaneous peak tolerance up to 1800°C), oxidation, and corrosion, while also exhibiting excellent adhesion to substrates such as metals, ceramics, and graphite. From ultra-high temperature components in aerospace engines and thermal protection systems for hypersonic vehicles, to high-temperature process fixtures in semiconductors and thermal management modules for new energy, and further to radiation-resistant components in nuclear energy, IOTA 9120 provides a fully controllable solution from molecular design to end performance. Choosing IOTA 9120 means you are no longer a passive user of materials, but an active designer of their ultimate performance. Let us collaborate to customize the perfect answer to future extreme challenges with programmable material intelligence.

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