As fields like aerospace and energy chemical engineering continuously push the physical limits of materials, and as ceramics or resins can no longer meet complex and evolving application demands, a revolution in materials science is imperative. We invite you to witness Organopolyborosilazane IOTA 9120 – this is not merely a ceramifiable precursor polymer, but an unprecedented intelligent materials platform whose performance can be “programmed and designed.” It perfectly integrates the processing convenience of polymeric materials, the ultimate performance of ceramics, and application-oriented performance customizability.

The epoch-making significance of IOTA 9120 lies in its revolutionary “processing flexibility” and “performance designability.”

Flexible Processing, Adapting to Your Production Line:
As a liquid precursor, its low viscosity allows easy dilution with dry solvents, facilitating various processes like spraying and impregnation. It offers two efficient curing pathways: thermal curing at 120-180°C, or rapid hydrosilylation curing at a milder 80-100°C with a platinum catalyst, with a curing time of only 2-5 hours. This flexibility enables seamless integration into your existing production workflows.

Designable Performance, Realizing Your Vision:
The true magic of IOTA 9120 is that its final ceramic properties can be “programmed” through pyrolysis conditions. This represents a leap for materials from “passive use” to “active design”:

• Composition Customization: By precisely selecting the pyrolysis atmosphere, you can actively “design” the final ceramic's chemical composition – generating SiC and Si₃N₄ in nitrogen/argon, predominantly forming Si₃N₄ in ammonia, and obtaining SiBOCN in air.

• Structure Control: High-performance amorphous ceramics are obtained below 1600°C, which transform into crystalline ceramics above 1600°C, meeting different operational requirements for thermal stability and mechanical strength.

• Composite Optimization: Its pyrolysis process can synergize with various fillers to further fine-tune the final product's microstructure and macroscopic properties, achieving true “tailor-making.”

The resulting SiBCN ceramic exhibits exceptional high-temperature resistance, oxidation resistance, and outstanding mechanical properties, while also showing excellent adhesion to substrates like metals, ceramics, and graphite. From ultra-high temperature components in aircraft engines and semiconductor heat treatment equipment, to thermal protection systems for new energy batteries and radiation-resistant components in nuclear energy, IOTA 9120 provides a one-stop solution from liquid resin to customized high-performance ceramics.

Choosing IOTA 9120 means you are no longer merely a “user” of materials, but a “designer” of their ultimate performance. Let us collaborate to pioneer a new era for extreme environment applications with programmable material intelligence.
       Room termperature curing polysilazane, pls check IOTA 9150, IOTA 9150K.       
       High termperature curing polysilazane, pls check IOTA 9108, IOTA 9118.