In the field of material protection, finding a coating material that balances ease of application, adaptability to various scenarios, and long-lasting performance has always been the industry's goal. Organosilicon polysilazane IOTA 9150, with its unique molecular structure and diverse properties, breaks through the limitations of traditional materials, becoming a preferred solution across multiple fields such as industry, electronics, and construction, redefining the core value of protective materials.



The superior performance of IOTA 9150 stems from its unique molecular structure. As a liquid polysilazane containing a silicon-nitrogen structure and with methyl groups as functional groups, its core advantage originates from the reactive properties of the -Si-NH-Si bond. This special chemical bond allows it to achieve room-temperature self-curing without complex processes, rapidly forming a dense protective layer through hydrolysis and oxidation reactions with moisture in the air. For even higher efficiency, a high-temperature curing mode can further optimize performance and flexibly adapt to different production rhythms.Meanwhile, the -Si-NH-Si bond can react rapidly with the -OH groups on the substrate surface to form a strong chemical bond. Even when facing substrates with different properties such as metals, ceramics, and plastics, it can achieve excellent adhesion and reach the 0-level standard in cross-cut adhesion testing.

In terms of performance, IOTA 9150 offers "all-around" protection. Its low viscosity provides excellent application compatibility, allowing for application via various methods such as smearing, dipping, spraying, and brushing. It can meet the ultra-thin coating needs of precision electronic components as well as the overall protection requirements of large industrial equipment. The coating thickness can be precisely controlled between 1-8μm without affecting the original precision of the substrate. The three-dimensional cross-linked structure formed after curing gives it core advantages such as non-flammability, oxidation resistance, and corrosion resistance. It withstands over 5000 hours of salt spray testing and maintains structural integrity even in strong acid, strong alkali, and high-temperature environments, effectively resisting the penetration of corrosive media.

Even more noteworthy is its functional extensibility. Leveraging its low surface energy, the coating exhibits excellent hydrophobic properties and anti-graffiti effects, with a water contact angle exceeding 150°, achieving a "lotus effect." Dust, oil, and graffiti can be washed away by rain or simply wiped away, significantly reducing maintenance costs. Adding an appropriate amount of catalyst to the resin further promotes the Si-H and Si-NH-Si bond reactions, further enhancing mechanical properties and providing a more robust structural support for the composite material.

In terms of application scenarios, IOTA 9150 is suitable for almost all industries. In the coatings field, it can be used for high-temperature corrosion protection of automotive parts and self-cleaning coatings for building exterior walls, replacing imported products and reducing costs by 40%-60%. As an adhesive, it can solve the sealing problem of heterogeneous materials and meet the precision manufacturing needs of new energy battery packs, automotive lighting components, etc. In the field of non-combustible composite materials and polymer-based composite materials, its ceramicization conversion ability can improve the high-temperature resistance of materials, and the long-term service temperature can reach above 800℃. In the glass and abrasives field, the coating, which combines light transmission and wear resistance, can extend the service life of products.

From pioneering high-temperature protection in the aerospace field to large-scale applications in civilian industries, the technological iteration of polysilazane materials has never stopped. IOTA 9150, with its core advantages of "easy application, strong adhesion, and comprehensive protection," not only breaks through the performance bottlenecks of traditional materials in extreme environments but also provides upgrade solutions for various industries at a high cost-performance ratio. Whether it's industrial equipment seeking long-lasting protection or public facilities requiring easy cleaning, this multifunctional organosilicon polysilazane is becoming a core force driving material upgrades