Environmental simulation and performance testing technology
Environmental simulation technology: It can simulate various complex environmental conditions faced by polysilazane in practical application scenarios of smart grids, such as high temperature, high humidity, salt spray, strong electric fields, etc. By establishing an accurate environmental simulation laboratory and using advanced temperature and humidity control equipment, electric field generation devices, salt spray boxes, etc., it can accurately evaluate the stability, durability, and potential impact of the formula on the environment in different environments, providing a basis for formula optimization.
Performance testing technology: equipped with comprehensive and accurate performance testing techniques, including but not limited to insulation performance testing (such as dielectric constant, breakdown strength determination, etc.), mechanical performance testing (such as hardness, toughness testing, etc.), environmental performance testing (such as biodegradation rate determination, harmful substance content analysis, etc.). With the help of professional testing instruments such as dielectric analyzers, universal material testing machines, gas chromatographs, etc., multi-dimensional performance evaluations are conducted on the developed environmentally friendly polysilazane formula to ensure that it meets the application requirements of the smart grid field.
Computational Chemistry and Materials Design Technology
Molecular simulation calculation: Using computational chemistry software and algorithms to simulate the molecular structure of polysilazane and its interactions with other additives. By using quantum mechanics calculations, molecular dynamics simulations, and other methods, the performance changes, reaction activity, and environmental behavior of polysilazane under different formulations can be predicted, assisting in the screening of more promising environmentally friendly formulations, reducing experimental blindness, and improving research and development efficiency.
Application of Materials Genomics: With the concept and methods of Materials Genomics, a database of materials related to polysilazane is established, integrating various information such as chemical structure, synthesis process, performance data, and environmental impact. Through big data analysis and machine learning technologies, the correlation between material properties and environmental attributes is explored, providing scientific guidance for the rapid and accurate development of new environmentally friendly polysilazane formulations.

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