Plane Mirror Projector Optical Mirror Laser Reflection Infrared Medium Mirror

Dielectric mirrors achieve high reflectivity through the multilayer dielectric film interference effect, differing from traditional metal mirrors that rely on the material's inherent reflective properties. Their core structure involves alternately depositing high-refractive-index (e.g., TiO₂) and low-refractive-index (e.g., SiO₂) dielectric layers on a glass or crystal substrate. Through reflection, refraction, and interference at each layer interface, specific wavelengths of light are almost entirely reflected, while other wavelengths are transmitted or absorbed. For example, dielectric mirrors commonly used in laser applications can achieve over 99.9% reflectivity at 1064 nm wavelength while suppressing interference from other wavelengths.

II. Key Technical Advantages

• High Reflectivity and Controllable Bandwidth: By optimizing layer thickness and number (typically 10-100 layers), high reflectivity (>99.5%) can be achieved for specific wavelengths (e.g., ultraviolet, visible, infrared), supporting both narrowband (e.g., laser lines) and broadband (e.g., visible spectrum) designs.
• Low Absorption and High Thermal Stability: Dielectric materials exhibit extremely low light absorption (compared to metal mirrors' ~5%-10% absorption), making them suitable for high-power laser systems. Some high-temperature-resistant dielectric films can withstand temperatures above 1000°C, avoiding failure due to oxidation that affects metal films.
• Adjustable Polarization Properties: Through layer design, polarization-selective reflection (e.g., high transmission for P-polarization, high reflection for S-polarization) can be achieved for use in polarized laser systems or optical isolators.

III. Main Application Scenarios

• Laser Technology: High-power laser resonant cavities, beam steering systems, and laser cutting/welding equipment require tolerance to high energy densities while maintaining reflective precision.
• Precision Optical Instruments: Spectrometers, interferometers, and astronomical telescopes use dielectric mirrors as spectral components to filter specific wavelengths through narrowband reflection.
• Medical and Communication: Beam control in laser therapy devices (e.g., ophthalmic surgical instruments) and wavelength-selective mirrors in fiber optic communications.

IV. Technological Development Trends

• Adaptation to Extreme Environments: Development of dielectric mirrors resistant to radiation and space conditions for applications in satellite remote sensing and deep-space exploration.
• Integrated Design: Combination with micro-optical elements (e.g., microlens arrays) to realize miniaturized, multifunctional optical systems.
• Ultra-Broadband High Reflectivity: Overcoming traditional dielectric mirror bandwidth limitations through gradient-index films or photonic crystal structures to cover the full spectrum from visible to infrared light.