Amino fluorosilicone oil has recently achieved a revolutionary breakthrough in the fields of ultra-precision optical device manufacturing and multifunctional smart coatings. Leveraging the ultra-high reactivity of amino functional groups and the exceptional environmental stability of fluorosilicon segments within its molecules, this material has successfully overcome the long-standing technical challenge of optical component interface failure under extreme temperature variations, high humidity, and intense radiation. Simultaneously, it has endowed a new generation of smart optical surfaces with multiple functions such as self-cleaning, high transmittance, and spectrum modulation, becoming a core innovative driver in the high-end optoelectronics industry and green building sector.

Research indicates that interfaces bonded and treated with amino fluorosilicone oil achieve 90° peel strength as high as 15-22 kN/m, retaining over 98% strength after rigorous dual 85 aging tests (85°C/85% relative humidity, 2000 hours) and a thousand cycles of thermal shock (-60°C to 150°C). Its refractive index (1.38-1.42) enables near-perfect matching with various optical glasses and crystals, with interfacial optical loss below 0.1%. Its extremely low moisture absorption (<0.05%) and outstanding weather resistance ensure the long-term stable service of optical systems in harsh environments such as space and marine applications.

In high-end manufacturing, this material has become a key interfacial material in the active splicing process for large space telescope primary mirrors, achieving sub-micron splicing accuracy and nano-level long-term surface figure stability. In the manufacturing of extreme ultraviolet lithography machines, serving as a stress-adaptation layer for optical components, it ensures the ultimate imaging performance of the optical system across the full operating temperature range. In the consumer electronics sector, ultra-thin optical clear adhesive developed based on it has increased the fold durability of flexible displays to over 500,000 cycles without transmittance degradation.

Another milestone application of this material lies in the development of multifunctional smart optical coatings. Through advanced nanocomposite technology, its derivative coatings achieve superhydrophobic self-cleaning, active anti-frosting, and dynamic infrared thermal management functions while maintaining visible light transmittance greater than 99%. Architectural glass curtain walls employing this technology enable intelligent regulation of building energy consumption while significantly reducing maintenance costs, and have been successfully applied in several iconic green building projects.

Authoritative industry experts point out that the series of breakthroughs achieved by amino fluorosilicone oil signify that specialty silicone materials have officially ascended from traditional supporting roles to become key platform materials determining the performance of high-end optical systems and enabling smart surface functionalities. It not only provides localized material solutions for multiple national major projects but will also lead the optoelectronic manufacturing, green building materials, and advanced display industries toward a high-performance and sustainable future at an accelerated pace.