In the current era of rapid progress in materials science, a novel material known as silicon boron carbon nitride (SiBCN) is quietly making its mark, showcasing immense application potential across numerous domains thanks to its unique properties.

SiBCN serves as a crucial raw material for fabricating high-performance composite ceramics. Traditional ceramic materials often fall short in terms of strength and toughness. However, SiBCN composite ceramics integrate a multitude of superior characteristics, enabling them to enhance the reliability and lifespan of equipment through their high hardness and excellent wear resistance. This makes them ideal for use in engine components within the aerospace sector as well as core components of precision machinery.

In the realm of high-temperature environmental monitoring, high-temperature ceramic sensors crafted from SiBCN stand out as pioneers. Capable of operating stably in extreme temperatures exceeding 800°C, these sensors accurately detect changes in parameters such as temperature and pressure. Their widespread application in high-temperature industrial settings like metallurgy and chemical engineering ensures the safety and efficiency of production processes.

SiBCN also plays a significant role in the electromagnetic field. The electromagnetic materials derived from it exhibit exceptional absorption and shielding capabilities against electromagnetic waves. In an era of proliferating electronic devices, these materials mitigate electromagnetic interference between devices and effectively prevent information leakage, earning them the title of "electromagnetic guardians" in fields such as 5G communication and radar systems.

In the new energy sector, the application of SiBCN in lithium-ion battery anode materials is particularly noteworthy. Compared to traditional graphite anodes, SiBCN anodes boast a higher theoretical specific capacity, significantly boosting the energy density of lithium-ion batteries. This translates to longer driving ranges for electric vehicles and extended battery life for electronic devices, injecting fresh impetus into the development of new energy sources.

Moreover, SiBCN can transform into a high-temperature-resistant and oxidation-resistant material. When spacecraft traverse the atmosphere, they encounter severe high-temperature ablation. SiBCN coatings form a dense protective layer, shielding spacecraft from high temperatures and oxidative erosion, thereby safeguarding their safety.

From industrial manufacturing to cutting-edge technology, SiBCN is continuously expanding its application horizons as a "jack-of-all-trades," offering new possibilities for the development of various industries. We eagerly anticipate its future unlocking of even more "cutting-edge" application scenarios.

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