When extreme environments of high temperature, oxidation, and complex atmospheres continuously challenge material performance boundaries, when traditional materials struggle to balance "processability" with "ultimate performance," are you searching for a truly intelligent solution?

Organoborosilazane IOTA 9120 is the revolutionary material engineered for this purpose. This is more than a high-performance resin; it is a programmable liquid ceramic synthesis system. By introducing the unique properties of boron into the classic polysilazane it creates an unprecedented atmosphere-directed transformation capability, allowing you to "customize" advanced ceramic materials for different extreme operating conditions through simple process selection.

Core Technology: Boron-Enabled Intelligent Transformation

The breakthrough of IOTA 9120 lies in its unique Si-N-B molecular structure and multi-path conversion technology:

Dual Intelligent Curing Pathways: Unprecedented process flexibility

• Thermal Cross-linking Path: Achieves cross-linking curing at 120-180°C, compatible with both air and inert atmospheres

• Catalytic Addition Path: Through platinum catalysis, enables gentle curing via hydrosilylation at 80-100°C within 2-5 hours

Revolutionary Atmosphere Programming Technology: Directional synthesis of target ceramics through controlled pyrolysis atmospheres

• Nitrogen/Argon Atmosphere: Yields SiC and Si₃N₄ composite ceramics, balancing high strength with excellent thermal shock resistance

• Ammonia Atmosphere: Main product is Si₃N₄ ceramic, offering oxidation resistance and high-temperature stability

• Air Atmosphere: Forms unique SiBOCN ceramic with superior oxidation and corrosion resistance

Exceptional Process Adaptability: Low viscosity supports various processing methods including impregnation, coating, and infiltration, exhibiting excellent adhesion to substrates like metals, ceramics, and graphite.

Product Characteristics & Application Value

Exceptional Material Properties:

• High ceramic yield with excellent conversion efficiency

• Capable of preparing high-performance SiBCN-based ceramics

• Pyrolysis products remain amorphous below 1600°C, beginning crystallization above 1600°C

• Final ceramic properties can be further tuned through fillers

Broad Application Prospects:

• Next-generation aerospace thermal structural components

• Critical components for high-temperature engines and gas turbines

• High-performance braking systems and high-temperature bearings

• Semiconductor manufacturing high-temperature fixtures and carriers

• Corrosion-resistant coating systems for extreme environments

Professional Usage Guidelines:
The product can be diluted with dry solvents but must be strictly protected from water, alcohols, acids, bases, and other protic substances. Storage and handling in dry, inert environments is recommended.

Creating Unique Value

Choosing IOTA 9120 provides you with:

• Design Freedom: From complex components to fiber-reinforced composites, breaking traditional ceramic forming limitations

• Performance Customization: Through atmosphere selection, specifically optimizing material properties for oxidation resistance, thermal shock resistance, or corrosion resistance

• Process Simplification: Integrated precursor solution significantly reduces manufacturing costs for complex ceramic parts

• Innovation Space: Provides new possibilities for forward-looking material design and application development

In today's increasingly competitive high-temperature materials landscape, IOTA 9120 offers a shortcut to the forefront of material innovation through its unique programmability and final performance. This is not merely a material choice but an upgrade in technological strategy—allowing liquid intelligence to crystallize in high temperatures, building indestructible performance through controlled chemistry.