Key Features

• High Light Transmission: Quartz material can transmit a wide range of light spectra from ultraviolet to far infrared, reducing light energy loss and improving the efficiency of laser systems.
• High Heat Resistance: The quartz vibrating mirror can withstand high-temperature working environments while maintaining optical performance stability.
• High Chemical Stability: Resistant to corrosion from various chemical environments, making it suitable for harsh working conditions.
• High Precision and Stability: Capable of precise laser beam scanning and positioning, ensuring high-quality marking and cutting results.
• Long Service Life: Offers a long lifespan, resistant to both high and low-temperature environments, meeting the demands of various industrial applications.

Applications

• Laser Marking: Used for precise marking of object surfaces, widely applied in industries such as electronics, automotive, and aerospace.
• Laser Cutting: In laser cutting machines, it controls the precise scanning of laser beams, suitable for cutting metals, plastics, glass, and other materials.
• Laser Welding: In laser welding equipment, it precisely controls the scanning and focal position of the laser beam to ensure high-quality welds.
• Laser Engraving: Achieves high-precision engraving for applications in artwork, electronics, and other industries.
• Precision Laser Processing: Widely used in precision processing technologies such as micro-machining and surface treatment.

Key Features

• High Precision and Stability: The silicon vibrating mirror provides excellent light reflection control, allowing precise adjustments of beam reflection angles and intensities.
• Superior Thermal Stability: It can operate in high-temperature environments without being affected by thermal degradation over time.
• High Reflectivity: Silicon materials offer excellent light reflectivity, improving the optical efficiency of the system.
• Robust Mechanical Strength: Silicon’s high mechanical strength makes it suitable for high-speed and high-load working conditions.
• Adaptability to Harsh Environments: With strong chemical stability, it maintains stable performance even in high humidity, strong corrosive, or other challenging environments.

Applications

• Laser Processing: Widely used in laser marking, laser cutting, and laser welding, where precise control of laser beam scanning enhances processing accuracy and efficiency.
• Optical Scanning Systems: Integral in laser scanners, microscopes, and similar equipment, improving scanning speed and precision.
• LiDAR (Light Detection and Ranging): Used as a mirror component in LiDAR systems, helping with precise beam scanning and imaging.
• Optical Communication and Sensors: In optical sensors and optoelectronic detectors, the silicon vibrating mirror helps improve the accuracy and efficiency of optical signal transmission.
• Integrated Circuits and Photonic Crystal Technologies: Also employed in integrated circuits, photonic crystals, and micro/nano optics, facilitating more efficient information processing and storage.

Key Features

• High Heat Resistance and Thermal Conductivity: Thanks to the ceramic glass material, PIG offers excellent high-temperature performance and superior thermal conductivity, ensuring stable operation in high-temperature environments.
• High Refractive Index and Transparency: The high refractive index and transparency of ceramic glass enhance the excitation efficiency of the phosphors, increasing light efficiency and brightness.
• Reduced Light Degradation: Compared to traditional fluorescent materials, PIG exhibits significantly less light degradation, ensuring long-term stable luminous performance.
• All-Inorganic Composite Material: As an all-inorganic composite, PIG offers enhanced durability, reliability, and stronger resistance to light degradation, making it highly adaptable across a wide range of applications.
• Customizable Production: PIG can be fabricated with different phosphors and concentrations to meet specific color temperature and BIN requirements, catering to various optical needs.
• Easy to Process: The product is in the form of circular plates and can be cut and customized according to specific application needs, making it convenient for use in different devices.

Applications

• LED Lighting: Widely used in high-performance LED lighting, especially in environments requiring high brightness and stable luminous output, such as commercial and residential lighting.
• Backlighting: Used as a backlight source for LCDs, providing efficient, uniform light to enhance display performance.
• Optical Instruments: Suitable for optical instruments, especially in devices where high optical efficiency and stability are critical.
• Automotive Lighting: Used in automotive LED lighting systems to enhance the brightness and stability of vehicle lighting.
• High-Power Applications: Ideal for high-power LEDs and other lighting systems, especially in environments with high demands for heat resistance and thermal conductivity.
• Medical Devices: Used in lighting systems for medical devices, ensuring stable and efficient light output.

Key Features

• High Transmittance: The colorless glass plane mirror has excellent light transmission properties, ensuring efficient light transfer.
• Precision Surface Treatment: The mirror surface is finely polished, achieving high flatness and stable reflection.
• Diverse Material Options: Various series of colorless optical glass materials can be chosen based on the required optical performance.
• High Reliability: Manufactured through rigorous processing and quality control, ensuring defect-free surfaces for long-term use.
• Excellent Optical Performance: High reflectivity and excellent light transmission make it suitable for complex optical systems.

Applications

• Optical Instruments: Used as reflective elements in various optical instruments to enhance optical performance.
• Laser Systems: Used for laser beam reflection and control to ensure stable propagation of the laser beam.
• Microscopes: Functions as a mirror in microscopes to help achieve precise imaging.
• Photography Equipment: Used in lens systems to improve image quality and optical performance.
• Scientific Research: An essential optical component in fields such as physics experiments and optical testing.
• Visual Devices: Used in various visual devices to enhance optical effects and image clarity.

Key Features

• Generation of Bessel Beams: Exhibits non-diffraction characteristics, maintaining a constant light intensity distribution over the focal depth range, making it suitable for applications requiring stable beam intensity distribution.
• High-Precision Beam Control: Converts collimated light into annular beams, with the diameter of the light rings increasing proportionally with the image distance while the thickness of the rings remains unchanged.
• Strong Adaptability: By adjusting the base angle and focal depth, conical lenses can meet various application needs, adapting to different laser and optical systems.
• Stable Optical Performance: Conical lenses offer high optical purity and stable optical performance, ensuring beam quality remains consistent during long-term use.

Applications

• Laser Beam Adjustment: Commonly used to generate annular beams in laser measurement, laser collimation, and other related fields.
• Research and Medical: Widely used in research, medical imaging, and laser therapy applications, especially in experiments and treatments that require high-precision beams.
• Optical System Design: Used in the design of optical systems to adjust beam morphology and meet various optical design requirements.
• Measurement and Detection: Applied in high-precision optical measurement and detection systems, particularly in cases where Bessel beams or annular beams are needed.

Key Features

• High Temperature Stability: Made from fused silica, this lens offers excellent thermal stability and a low thermal expansion coefficient, making it suitable for high-temperature environments.
• High Precision Design: Available in both positive and negative focal lengths, it precisely adjusts the shape and size of light beams.
• Versatile Applications: Can convert beams into different shapes to meet precise needs, such as laser beam shaping and other precision applications.
• High-Quality Manufacturing: The lens is made using advanced processing techniques, including glue disc polishing, high-speed polishing, annular polishing, and CNC polishing, ensuring high precision and quality.

Applications

• Laser Systems: Used for laser line generation and beam shaping, ensuring accuracy and quality in laser output.
• Optical Imaging: Applied in precision imaging systems to adjust image sizes and shapes.
• Laser Processing: Used in laser processing applications such as laser cutting, engraving, and marking for beam shaping.
• Beam Adjustment: Widely used in laser systems for beam focusing, divergence, and deformation.

Key Features

• Wide Spectrum Transmittance: Suitable for ultraviolet, visible, and near-infrared spectral regions, ensuring excellent optical performance.
• Low Dispersion: Effectively reduces beam divergence and corrects chromatic aberration, providing higher image quality.
• High Uniformity and High Damage Threshold: Offers excellent resistance to damage, making it suitable for high-power laser systems.
• Superior Physical Properties: While calcium fluoride is softer and more prone to surface scratches, it provides excellent optical properties and a low refractive index.
• Precision Manufacturing: Made using advanced polishing techniques such as glue disc polishing, high-speed polishing, annular polishing, and CNC polishing, ensuring high precision and surface quality.

Applications

• Laser Systems: Used for beam collimation, beam shaping, and beam focusing, enhancing the efficiency of laser systems.
• Optical Instruments: Widely used in telescopes, microscopes, and other optical instruments to adjust image size and improve image quality.
• Optical Components Manufacturing: Serves as a key component in optical systems, such as mirrors and prisms, meeting the demands of precision optics.
• Laser Processing: Used in laser processing to modify beam shapes and sizes for precise control in manufacturing and cutting processes.

Key Features

• High Precision: Precision machining and polishing result in a superior surface quality, ensuring minimal wavefront distortion.
• Strict Standards: The lens is manufactured with strict requirements for central and edge thickness, ensuring stable performance.
• Good Thermal Stability: Maintains excellent optical performance even in high-temperature environments.
• Superior Optical Performance: Features minimal optical errors, making it ideal for high-precision optical systems.

Applications

• Laser Systems: Used for beam collimation, focusing, and expansion, offering precise optical control.
• Optical Instruments: Serves as a high-precision optical component in various optical instruments.
• Optical Communication: Used in optical communication systems for beam transmission and regulation.
• Imaging Systems: Suitable for high-precision imaging applications, ensuring image quality and accuracy.
• Beam Shaping: Used for beam shaping and collimating, ensuring stable beam quality.

Key Features

• High Transparency and Low Reflectivity: Excellent optical transmission in both visible and infrared ranges, minimizing light loss.
• High Thermal Stability: Germanium has exceptional thermal stability, making it suitable for use in optical systems operating in high-temperature environments.
• Environmental Resistance: Germanium offers good inertness to air, water, acids, and alkalis, ensuring stable performance in harsh environmental conditions.
• High Refractive Index: With a high refractive index, it effectively enhances the numerical aperture (NA) of the system and improves optical performance.
• Precision Manufacturing: Utilizes precise manufacturing and polishing processes to ensure surface quality and dimensional accuracy.

Applications

• LiDAR Systems: Used in LiDAR systems as a beam modulation, collimating, or focusing element.
• Optical Sensors: Widely used in high-precision optical sensors, providing excellent transmission performance.
• Spectrometers: In infrared spectrometers, it is used for beam focusing and collimation.
• Infrared Imaging: Due to its excellent transparency and high thermal stability, it is frequently used in thermal imaging systems, especially in demanding environments.
• Infrared Optical Systems: As a key component in infrared optical systems, it improves imaging quality and system stability.
• Harsh Environment Applications: The Germanium Crescent Lens is ideal for optical systems used in high-temperature, high-pressure, or other extreme environments.

Key Features

• High Optical Transmission: Provides high transmission in both visible and infrared wavelengths, ensuring efficient light transmission.
• Low Reflectivity and Low Absorption: Minimizes light losses, enhancing the overall performance of optical systems.
• High Thermal Stability: Zinc Selenide performs exceptionally well in high-temperature environments, making it suitable for systems with high thermal loads.
• Anti-Reflective Coating: The surface is precision-polished to reduce reflection losses and improve system efficiency.
• Precision Manufacturing: Manufactured using high-precision cutting, grinding, and polishing techniques to ensure the lens shape and optical quality.
• Coating Options: Often coated to further improve transmission and anti-reflection properties.

Applications

• LiDAR Systems: Used as an optical element in LiDAR systems for beam shaping and focusing.
• Optical Sensors: Widely used in optical sensor systems to improve measurement precision.
• Spectrometers: Serves as a transparent element in infrared spectrometers, enabling accurate spectral data collection.
• Thermal Imaging Systems: Utilized in thermal and infrared imaging systems for its excellent infrared transmission properties.
• Medical Systems: As a key optical component in medical optical systems, providing precise imaging and light transmission.
• Infrared Imaging: Widely applied in infrared imaging systems, enhancing system image quality and stability.