Product Introduction:
Fused silica is the amorphous (glassy) state of silicon oxide (quartz, silica). It is a typical glass with a long-range disordered atomic structure. It provides its high service temperature and low coefficient of thermal expansion by cross-linking its three-dimensional structure.
The plano-concave lens is composed of a flat surface and a concave spherical surface, which can produce negative spherical aberration and is often used in systems where the light is expanded or the focal length is increased to balance the deviation of other lenses.
Our Company can provide Fused Silica(SiO2) plano-convex lenses with diameters from 2-300mm and thicknesses from 0.12-60mm (accuracy up to 20-10, 1/10L@633nm), with 4 major processes: gel disc polishing, high speed polishing, ring polishing and CNC polishing, with ZYGO, AFM, reflection and transmission eccentric meters, 15 second goniometer, UV gel centering system, non-contact Laser. Thickness gauge, 2D imager and sphere diameter gauge to ensure the accuracy of data.
Coating Selection:
MgF2, UV-AR,UV-VIS ,VIS-EXT, VIS-NIR, NIR I, NIR II, Telecom-NIR,SWIR ,SWIR ,YAG-BBAR.
Fused silica is typically used for applications from the ultraviolet (UV) to the near infrared (NIR). Its high transmittance, good heat resistance, and excellent environmental durability make it suitable for use in laser equipment, emission and detection protection equipment, and imaging systems in the UV spectrum.
Our company offer fused silica plano-concave lenses in various sizes and focal lengths.
Plano-concave lens with one concave side and one flat side can spread the light out and has a negative focal length.Plano-concave lenses are often used for beam extension, projection and focal length expansion of optical systems.The plano-concave lenses has a negative focal length and negative spherical aberration, which can be used to offset the aberration of other lenses in the system. To obtain a smaller spherical aberration, the collimated beam should be incident on the concave side of the plano-concave lenses when the incident beam is collimated.
The important parameters of a plano-concave lens are: size, focal length, design wavelength, finish, face accuracy, eccentricity, substrate material and other attributes. Suitable parameters of plano-concave lenses can be selected according to specific applications.
Natural quartz, also called quartz glass, which is synthesized by a number of processes to form fused silica, is the most common and most important material for optical components. Compared to natural quartz, synthesized fused silica has a higher radiometric hardness and higher absolute transmittance. This enables it to have excellent optical properties in the ultraviolet, visible, near-infrared, and infrared bands, as well as in the terahertz band.
Compared to K9 and bk7 materials, fused silica offers higher thermal properties and purity, as well as excellent environmental durability, making it more suitable for use in harsh applications.
Coating refers to coating a transparent electrolyte film or metal film on the surface of the substrate material by physical or chemical methods. The purpose is to change the reflection and transmission characteristics of the material surface to reduce or increase the reflection, beam splitting, color separation, light filtering, polarization and other requirements.We can provide various optical coatings such as anti-reflective films, high-reflective films, spectral films, and metallic films. Broadband anti-reflective films are available for UV, visible, NIR and mid-infrared wavelengths.
Natural quartz, also called quartz glass, is synthesized by a number of processes to form fused silica (Fused silica). It is the most common and most important material for optical components. Compared to natural quartz, synthetic fused silica has a higher radiometric hardness and higher absolute transmittance. Therefore, it is able to have good optical properties in the UV, visible, near IR, IR bands, and terahertz bands.
According to the transmittance of different bands, quartz transmittance is classified as follows.
JGS1 Far Ultraviolet Optical Quartz Glass 185- 2500nm
JGS2 Ultraviolet Optical Quartz Glass 220- 2500nm
JGS3 Infrared Optical Quartz Glass 260- 3500nm
Transmission spectroscopy:
These two images show the transmittance of fused silica and natural quartz respectively.
The above graph shows the transmission spectra of several commercial fused silica models, and it can be seen that they all have high transmission at 185-2600nm. Depending on the model, the transmission spectra vary slightly, for example, some models still have more than 80% transmission in the deep UV band at 165nm, some models have an absorption peak near 2800nm, and some models can maintain more than 80% transmission until 3500nm.
The chart below shows the transmission spectrum of natural quartz, which is only guaranteed to have high transmission from 270nm to 2600nm and much lower transmission in the UV band than fused silica. The reflectance of natural and fused quartz is basically the same, both are less than <10%. In the near UV band it is close to 10%, and at any time the wavelength increases, the quartz reflectance slowly decreases to approximately 6% in the near IR band.
Monocrystalline
●There are no visible grain boundaries or wicker-like stripes on the crystal surface when examined under naked eye daylight.
Sub-crystal
●When examined under naked-eye daylight, there are willow stripes on the surface of the crystal with an area < 1/6 (end diameter), and the willow stripes are not visible after polishing .
Polycrystalline
●When examined under naked-eye daylight, there are penetrating crystal boundary lines on the surface of the crystal, and the difference in the degree of light and darkness between the two sides of the crystal boundary lines is obvious.
●N-BK7
N-BK7 is the most commonly used optical glass for processing high quality optical components,, with excellent transmittance from visible to near-infrared wavelengths(350-2000nm), and has a wide range of applications in telescopes, lasers and other fields. N-BK7 is generally chosen when the additional benefits of UV fused silica (very good transmittance and low coefficient of thermal expansion in the UV band) are not required.
●UV fused silica
UV fused silica has a high transmission from the UV to NIR (185-2100nm). In addition, UV fused silica has better uniformity and lower coefficient of thermal expansion than H-K9L (N-BK7), making it particularly suitable for high power laser and imaging applications.
●Calcium fluoride
Due to its high transmittance and low refractive index within a wavelength of 180nm-8um, calcium fluoride is often used as windows and lenses in spectrometers and thermal imaging systems. In addition, it has good applications in excimer lasers because of its high laser damage threshold.
●Barium fluoride
Barium fluoride have high transmittance from the 200nm-11um and they are resistant to stronger high-energy radiation. At the same time, barium fluoride has excellent scintillation properties and can be made into various infrared and ultraviolet optical components. However, the disadvantage of barium fluoride is that it is less resistant to water. When exposed to water, the performance degrades significantly at 500℃, but it can be used for applications up to 800℃ in a dry environment. At the same time, barium fluoride has excellent scintillation properties and can be made into various infrared and ultraviolet optical components.It should be noted that when handling barium fluoride material, gloves must be worn at all times and hands must be washed thoroughly after handling.
●Magnesium fluoride
Magnesium fluoride is ideal for applications in the wavelength range of 200nm-6um. Compared to other materials, magnesium fluoride is particularly durable in the deep UV and far IR wavelength ranges. Magnesium fluoride is a powerful material for resistance to chemical corrosion, laser damage, mechanical shock and thermal shock. It is harder than calcium fluoride crystals, but relatively soft compared to fused silica, and has a slight hydrolysis. It has a Nucleus hardness of 415 and a refractive index of 1.38.
●Zinc selenide
Zinc selenide has high transmittance in the 600nm-16um and is commonly used in thermal imaging, infrared imaging, and medical systems. Also, due to its low absorption, zinc selenide is particularly suitable for use in high-power CO2 lasers. It should be noted that zinc selenide is a relatively soft material (Nucleus hardness 120) and is easily scratched, so it is not recommended for use in harsh environments. Extra care should be taken when holding, and cleaning, pinching or wiping with even force, and it is best to wear gloves or rubber finger covers to prevent tarnishing. Cannot be held with tweezers or other tools.
●Silicon
Silicon is suitable for use in the NIR band from 1.2-8um.Because of its low
density, silicon is particularly suitable in applications where weight
requirements are sensitive, especially in the 3-5um . Silicon has a Nucleus
hardness of 1150, which is harder than germanium and not as fragile as
germanium.It is not suitable for transmission applications in CO2 lasers
because of its strong absorption band at 9um.
●Germanium
Germanium is suitable for use in the near-infrared band of 2-16um and is well
suited for infrared lasers. Due to its high refractive index, minimal surface
curvature and low chromatic aberration, germanium does not usually require
correction in low power imaging systems. However, germanium is more
severely affected by temperature, and the transmittance decreases with
increasing temperature; therefore, it can only be applied below 100°C. The
density of germanium (5.33 g/cm³) is taken into account when designing
systems with strict weight requirements. Germanium lenses feature a
precision diamond lathe turned surface, a feature that makes them well suited
for a variety of infrared applications, including thermal imaging systems,
infrared beam splitters, telemetry, and in the forward-looking infrared (FLIR)
field.
●CVD ZnS
CVD ZnS is the only infrared optical material, other than diamond, that covers visible to long-wave infrared (LWIR), full wavelength and even microwave wavelengths, and is currently the most important LWIR window material. It can be used as windows and lenses for high-resolution thermal imaging systems, as well as for advanced military applications such as "tri-optical" windows and near-infrared laser/dual-color infrared composite windows.