Poly(dimethylsilane) offers multiple application advantages in the new energy industry, primarily reflected in the following aspects:

Preparation of High-Performance Ceramic Materials: Poly(dimethylsilane) serves as a precursor for the synthesis of polycarbosilane, which can be transformed into silicon carbide (SiC) ceramics and silicon carbide fibers through high-temperature pyrolysis. Silicon carbide materials exhibit excellent high-temperature resistance, oxidation resistance, and mechanical properties. In the high-end equipment manufacturing sector of the new energy industry, they can be used to fabricate components that withstand high-temperature environments, such as structural components in nuclear reactors and high-temperature-resistant support components in solar photovoltaic power generation equipment. This enhances the stability and service life of the equipment under harsh conditions.
Intermediate for Photovoltaic Materials: With silicon-silicon bonds in its molecular structure, poly(dimethylsilane) acts as an intermediate for the synthesis of organosilicon photovoltaic materials. In organic photovoltaic cells (OPVs), polymers derived from chemically modified poly(dimethylsilane) can improve the stability and photoelectric conversion efficiency of the cells. This contributes to enhancing the performance of solar cells, reducing costs, and promoting the widespread application of solar energy in the new energy sector. In flexible displays, its derivative materials can be used in functional layers, providing better display effects and flexibility for display devices powered by new energy sources. This meets the demands for flexible displays in areas such as interior displays for new energy vehicles and wearable devices.
Potential Advantages in Energy Storage Applications (Under Exploration): Although still in the exploratory stage, poly(dimethylsilane) holds potential application advantages in lithium-ion batteries and hydrogen energy storage. In lithium-ion batteries, it may aid in the development of high-performance electrode materials, improving the energy density, charge-discharge efficiency, and cycle stability of the batteries. This, in turn, enhances the range and performance of new energy devices such as electric vehicles. In the field of hydrogen energy storage, it may be involved in the development of novel hydrogen storage materials or related auxiliary materials, offering new ideas and solutions to address the challenges of hydrogen storage and transportation, thereby promoting the large-scale application of hydrogen energy in the new energy industry.

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