Amino fluorosilicone oil has recently achieved revolutionary progress in the fields of ultra-precision optical device bonding and assembly, as well as multifunctional smart coatings. Leveraging the ultra-high reactivity of amino functional groups and the exceptional chemical stability of fluorosilicon segments within its molecules, this material has overcome the technical bottleneck of optical-grade bonding interfaces being prone to failure in extreme environments. Simultaneously, it has endowed next-generation smart surfaces with multiple functions such as self-cleaning, high light transmittance, and resistance to extreme climates, becoming a core innovative material in high-end optoelectronic manufacturing and green building sectors.

Research shows that bonding interfaces treated with amino fluorosilicone oil achieve 90° peel strength of 15-22 kN/m, retaining over 98% strength retention after damp-heat aging (85°C/85% RH, 2000h) and high-low temperature cycling (-60°C to 150°C, 1000 cycles). Its refractive index (1.38-1.42) perfectly matches various optical glasses, crystals, and transparent polymers, with interfacial optical loss below 0.1%. More critically, its extremely low moisture absorption (<0.05%) and excellent resistance to UV and salt spray ensure the long-term stable service of optical systems in harsh environments such as marine, desert, and space.

In high-end manufacturing, the material has been used as a key interface adhesive in the primary mirror splicing process for China's large space telescope, achieving sub-micron splicing accuracy and nano-level long-term surface figure stability. In the manufacturing of Extreme Ultraviolet (EUV) lithography machines, as a material for high-precision positioning and stress relief layers of 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 optically clear adhesive (OCA) developed based on it has increased the fold durability of flexible screen smartphones to over 500,000 cycles with almost no light transmittance degradation.

Another major breakthrough of this material lies in the development of multifunctional smart coatings. Through nanocomposite technology, its derivative coatings achieve visible light transmittance >99% and haze <0.2%, while simultaneously realizing superhydrophobicity (contact angle >170°), self-cleaning, anti-frosting, and near-infrared spectrum modulation functions. Building curtain walls adopting this technology can achieve intelligent regulation of building energy consumption while reducing cleaning and maintenance costs by 50%. Currently, this technology has been successfully applied in energy-saving renovations of major projects such as Beijing Daxing International Airport.

Authoritative industry experts state that this series of breakthroughs by amino fluorosilicone oil signifies that silicone materials have officially advanced from traditional sealing and protection roles into a new stage as a platform material endowing high-end devices with composite "optical, mechanical, electrical, and thermal" functions. It not only addresses "bottleneck" material challenges in multiple national major projects but will also lead the optical manufacturing, green building, and consumer electronics industries toward higher performance and sustainable development, with immeasurable strategic value and market potential.