4 Advice to Choose a achromatic cemented lens

An achromatic lens is a type of optical lens designed to limit the effects of chromatic and spherical aberration. Chromatic aberration occurs when different wavelengths of light are refracted by different amounts, causing a failure to focus all colors to the same convergence point. This results in a blurred image with color fringes around the edges. Achromatic lenses are engineered to bring two wavelengths, typically red and blue, into focus in the same plane, thereby significantly reducing chromatic aberration.

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Achromatic lenses are usually made by combining two types of glass with different dispersion properties:

1. Crown Glass: A type of glass with low dispersion.
2. Flint Glass: A type of glass with high dispersion.

These two or more elements are cemented together to form a doublet lens. The combination of these materials helps to counteract the dispersion of light, effectively minimizing chromatic aberration.

Structure and Principle

A Positive Achromatic Lens is usually a doublet, made up of a positive low-refractive index element (such as crown glass) and a negative high-refractive index element (such as flint glass). This combination allows the chromatic aberration of one lens to be neutralized by the other, achieving the correction of chromatic aberration.

Applications

These lenses are widely used in fluorescence microscopy, image relaying, detection, and spectroscopy, among others. They provide almost constant focal lengths across a broad wavelength range, and compared to single lenses, they produce smaller light spots and clearer imaging.

Advantages

• Chromatic Aberration Correction: Effectively focuses two principal wavelengths of light, significantly reducing chromatic aberration.
• Improved Image Quality: Delivers clearer imaging and finer light spots compared to single lenses.
• Diverse Coating Options: Offers a selection of coatings such as VIS, NIR, SWIR to suit various application needs.

Manufacturing and Materials

Creation of Positive Achromatic Lenses involves the precise bonding of two selected materials, commonly N-BK7 and SF5 glass. The lens design parameters including radius of curvature, center thickness, and others are meticulously calculated to ensure optimal optical performance.

Typical Specifications (Example)

• Diameter: 50.80mm
• Effective Focal Length (EFL): 150.00mm
• Coating: Anti-Reflective Coating AR@400-700nm
• Materials: N-BK7/SF5
• Back Focal Length (BFL): 140.40mm
  Radius of Curvature (R1/R2/R3): 83.20mm, -72.10mm, -247.70mm respectively
• Center Thickness (CT): 15.00mm
• Surface Quality: Ranges from 40-20 to 60-40 depending on specifications

With precision imaging capabilities and chromatic aberration correction, Positive Achromatic Lenses are indispensable components in advanced optical systems, particularly in applications where image quality is of paramount importance.

Negative Achromatic Lenses are specially designed optical lenses for correcting chromatic aberrations, typically made by bonding two different types of glass materials—a low refractive index crown glass and a high refractive index flint glass. Unlike their counterpart, the Positive Achromatic Lenses, negative achromatic lenses primarily function to disperse, not focus, light rays.

Structure and Working Principle

The negative achromatic lens consists of a positive-dispersion crown glass lens paired with a negative-dispersion flint glass lens. The design aims to counteract the chromatic aberration produced by one lens with that produced by another, thus effectively correcting chromatic aberration. These lenses play a crucial role in various optical systems requiring light to diverge.

Application Fields

Negative achromatic lenses have a wide range of applications in optics, such as laser beam expanders, optical relay systems, and more. They offer a stable diverging angle across a wide wavelength and can produce a smaller and clearer spot and image compared to single lenses.

Advantages

1. Effective Chromatic Aberration Correction: The lens can disperse light rays of different wavelengths onto the same plane, significantly reducing chromatic aberration issues.
2. Superior Imaging Quality: Compared to single lenses, negative achromatic lenses provide clearer imaging quality and produce smaller light spots.
3. Diverse Configurations: Depending on different usage requirements, lenses can be configured with various coating options suitable for visible light, near-infrared (NIR), short-wave infrared (SWIR), and other wavelengths.

Manufacturing Materials

In production, negative achromatic lenses usually employ materials like N-BK7 and SF5. Lens manufacturing involves meticulous design of many parameters, such as the radius of curvature, center thickness, and edge thickness, to ensure optimal optical performance.

Typical Specifications

• Diameter: 50.80 mm
• Effective Focal Length: -150.00 mm
• Coating: Enhanced reflectivity coating for the 400-700 nm band
• Materials: Typically N-BK7 and SF5 glass
• Back Focal Length: -140.40 mm
• Radius of Curvature: R1 -83.20 mm, R2 72.10 mm, R3 247.70 mm
• Center Thickness: 15.00 mm
• Surface Quality: Varies from 40-20 to 60-40

Overall, negative achromatic lenses play a vital role in optical systems that require high precision diversion of light and correction of chromatic aberrations.

Achromatic Triplet Lenses represent an advanced optical technology specifically designed for the effective correction of chromatic aberrations and other types of optical anomalies. These lenses are composed of three distinct lens elements, typically two elements made of high refractive index materials encasing one made of a lower refractive index material. This arrangement not only significantly reduces aberrations, including distortion and spherical aberrations, but also provides clear, high-quality imaging results.

Structure and Working Principle

Achromatic Triplet Lenses usually feature a symmetrical three-element design, consisting of two high refractive index glasses (such as crown glass) and one low refractive index glass (like flint glass) bonded together through a precise adhesion process. This structural layout enables the lens to efficiently correct chromatic aberration and further reduce aberrations, such as pincushion distortion and spherical aberration, through its symmetry.

Contact us to discuss your requirements of achromatic cemented lens. Our experienced sales team can help you identify the options that best suit your needs.

Application Areas

With their excellent imaging properties, Achromatic Triplet Lenses are extensively used in fields that demand high-quality imaging. These include fluorescence microscopy, spectroscopy, surface inspection, and life sciences imaging, among others. The lenses are capable of providing excellent color correction and high-resolution image quality across a wide wavelength range.

Advantages

1. Chromatic Aberration Correction: The Achromatic Triplet Lenses can precisely adjust light of different wavelengths to the same focal plane, significantly reducing the occurrence of chromatic aberrations.
2. Reduced Aberrations: Thanks to the ingenious symmetrical design and precise manufacturing processes, distortions such as pincushion distortion and spherical aberration are effectively controlled and minimized.
3. High-Resolution Imaging: These lenses offer high-definition and high-quality imaging solutions for a variety of precision optical applications.

Manufacturing Materials and Processes

The production of Achromatic Triplet Lenses involves the precise bonding of lenses made from different types of materials. Typical lens materials include traditional optical glass, ultraviolet-grade fused silica (JGS1), infrared-grade fused silica (JGS3), and calcium fluoride (CaF2), among others. Key lens parameters, such as the radius of curvature, central and edge thickness, are meticulously designed to ensure optimal optical performance.

Typical Specifications

• Manufacturing Materials: Various, including optical glass, ultraviolet-grade fused silica, infrared-grade fused silica, and calcium fluoride.
• Dimensional Tolerances: Typically, ±0.03mm for standard factory specifications, with precision manufacturing achieving up to ±0.01mm.
• Center Thickness Tolerance: ±0.03mm as the standard factory specification, with manufacturing limits reaching ±0.02mm.
• Radius of Curvature Tolerance: ±0.3% as the standard factory specification, with manufacturing limits reaching ±0.2%.
• Surface Quality: Achieving a 20-10 level under factory standards, improving to a 10-5 level for higher demands.
• Irregularity: The common standard is 1/5 Lambda, with the limit for higher demands being less than 1/10 Lambda.
• Centration Deviation: Under normal factory conditions, centration can be controlled within 3 arcminutes (Arcmin), with manufacturing limits tightening to 1 Arcmin.

Achromatic Triplet Lenses play a crucial role in modern optical systems, especially in applications requiring high-precision imaging and chromatic aberration correction. Their high-quality design and manufacturing make them the preferred choice for many advanced optical applications.

Aspheric Achromatic Lenses merge the advantages of both aspheric and achromatic lenses, creating a sophisticated optical component. This unique combination allows them to deliver exceptional image quality and precise chromatic aberration correction.

Structure and Working Principle

These lenses are typically composed by bonding together two lenses: one achromatic lens and one aspheric lens. The design of the aspheric lens is aimed at mitigating the wavefront errors produced by traditional spherical lenses, thereby achieving more accurate image quality, reducing the RMS spot size, and approaching the diffraction limit.

Manufacturing and Material Selection

Commonly, these lenses are made from photosensitive polymers and glass optical components, with the polymer applied to one surface of the bonded lens pair. This method not only enables the lenses to be manufactured quickly within a short timeframe but also offers flexibility similar to traditional multi-element assemblies. However, the working temperature range of Aspheric Achromatic Lenses is quite narrow, restricted from -20°C to +80°C, and they are not suitable for Deep Ultraviolet (DUV) spectral transmission.

Key Advantages

1. Chromatic Aberration Correction: They effectively correct chromatic aberration, precisely focusing light of different wavelengths onto the same plane.
2. Reduction of Aberrations: Their aspheric design significantly reduces spherical aberration and wavefront errors, enhancing image quality.
3. Cost-Effectiveness: Compared to conventional multi-element optical systems, these lenses provide greater value for money.

Application Areas

Aspheric Achromatic Lenses are widely used in various high-precision optical systems, such as:

• Fiber focusing or collimation
• Imaging relay systems
• Detection and scanning systems
• High numerical aperture imaging systems
• Laser beam expanders

Technical Specifications

• Materials: Photosensitive polymers and glass optical lenses
• Operating Temperature Range: From -20°C to +80°C
• Main Applications: Including fiber focusing, imaging relays, detection scanning, and high numerical aperture imaging, among others

With their ingenious design and efficient manufacturing process, Aspheric Achromatic Lenses demonstrate outstanding optical performance and a broad spectrum of applications, making them an indispensable key component in modern precision optics and vision systems.

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Whether it’s for your scientific research project, photographic hobby, instrumentation, or any situation where precise imaging is required, our achromatic lenses will provide you with excellent color correction and image clarity. Choose Chineselens Optics for quality optical solutions and services that will help your projects and products reach new heights. Contact our experts today for a consultation!

Key Takeaways

• Achromatic lenses effectively correct chromatic aberration by aligning different wavelengths of light, thereby enhancing image quality across a broad spectral range in various optical systems.
• They combine two lens elements with differing dispersion properties to minimize chromatic aberration, resulting in sharper and clearer images particularly in telescopes and microscopes.
• Theses lenses are versatile and suitable for applications requiring accurate color rendition across the visible spectrum and into near-infrared and ultraviolet regions.
• While beneficial for high-quality imaging, these lenses may have limitations such as residual chromatic aberration and increased complexity and cost in manufacturing.

Understanding Achromatic Lenses and Chromatic Aberration

An achromatic lens, often referred to as an achromat, is a specialized optical lens designed to correct chromatic aberration—a distortion that occurs when white light is refracted into different color wavelengths within the spectrum.

Chromatic aberration is a common optical flaw that manifests when white light traverses through a single lens. As the light wavelengths pass through the lens material, they undergo differential refraction due to varying optical properties. Consequently, these wavelengths converge at distinct focal points within the image plane, preventing the simultaneous focus of all colors. This effect leads to the appearance of blurred color fringes between the contrasting areas of an image, resulting in a notable degradation of image quality.

To address the challenge posed by chromatic aberrations, achromatic lenses are employed. These optical components incorporate two or more lens elements, strategically engineered to align two specific wavelengths of light—typically red and blue—to converge at a shared focal point. This correction mechanism effectively mitigates the undesirable effects of chromatic aberration, ensuring improved image quality and color fidelity.

Achromatic Lenses

Merits of Achromatic Lenses:

• Chromatic Aberration Correction: They are primarily designed to correct chromatic aberration, a common optical defect where different colors of light focus at different points. These lenses combine two different lens elements, typically one with low dispersion and one with high dispersion, to minimize chromatic aberration, resulting in sharper and more accurate images.
• Improved Image Quality: By reducing chromatic aberration, achromatic lenses enhance image quality, particularly in optical systems like telescopes, microscopes, and camera lenses. This improvement is especially noticeable at high magnifications.
• Wide Spectral Range: Achromatic lenses are effective over a broad spectral range, making them suitable for applications across the visible spectrum as well as into the near-infrared and ultraviolet regions.
• Versatility: These lenses come in various shapes and sizes, making them versatile for a wide range of optical systems and applications. They can be configured as doublets, triplets, or even aspheric lenses to meet specific requirements.

Demerits of Achromatic Lenses:

• Limited Correction: While achromatic lenses are effective in reducing chromatic aberration, they may not completely eliminate it. Some residual chromatic aberration may still be present, especially in low-cost or less precise achromatic lenses.
• Complex Manufacturing: Achromatic lenses require careful selection of materials with specific dispersion properties, precise alignment, and cementing of lens elements. This complexity in manufacturing can result in higher production costs.
• Bulkiness: Achromatic lenses often consist of multiple elements, which can make them larger and heavier compared to simple lenses. This bulkiness may not be suitable for all applications.

When to Use Achromatic Lenses:

Then when should we choose Achromatics Lenses?

• High-Quality Imaging: Achromatic lenses are ideal when you require high-quality, color-corrected images. They are commonly used in cameras, telescopes, microscopes, and other optical instruments where accurate color rendering is crucial.
• Reducing Color Distortion: If your optical system exhibits noticeable color fringing or distortion, achromatic lenses can help minimize these effects, leading to clearer and more accurate results.
• Broad Spectral Range: When your application spans a wide spectral range, such as in spectroscopy or photography, achromatic lenses are preferred due to their ability to correct chromatic aberration across a range of wavelengths.
• Precision Optical Systems: In applications demanding precise and controlled optical performance, such as in scientific research, medical imaging, or aerospace, achromatic lenses are a suitable choice to ensure accurate results.
• Cost Considerations: While they can be more expensive than simple lenses, achromatic lenses provide a cost-effective solution when compared to more complex corrective optics like apochromatic lenses. Therefore, they are often chosen in scenarios where cost is a factor but optical quality is still critical.

In summary, achromatic lenses are valuable tools for correcting chromatic aberration and improving image quality in a wide range of optical applications. They are especially beneficial when color accuracy and performance across a broad spectral range are essential. However, their suitability depends on the specific requirements and constraints of your optical system.

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