d Institute of Physical Chemistry, and Abbe Center of Photonics, Friedrich Schiller University, Helmholtzweg 4, Jena D-07743, Germany

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12. Near-Infrared Radiation (NIR) Objectives: Near-infrared (NIR) range objectives in brightfield microscopy are tailored for laser applications, enabling precise observation within the near-infrared radiation spectrum. These NIR objectives are characterized by their Plan Apochromat design, infinity correction, and long working distance, making them ideal for applications involving this specific wavelength range.

6. Long Working Distance Objectives: These objectives have a greater distance between the lens and the specimen, making them suitable for applications where space is limited or for examining larger specimens.

10. Strain Free Polarizing Microscope Objectives: Strain-free polarizing microscope objectives are specialized lenses designed for use in polarizing microscopes. They are crafted to minimize birefringence, which is the distortion of light passing through a material under stress. These objectives allow for precise examination of transparent specimens, particularly those with mineral compositions, by reducing optical distortions related to internal strains. This makes them invaluable in geology, petrology, and materials science for studying crystalline structures and material properties.

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b Institute of Functional Interfaces (IFG), Karlsruhe Institute of Technology (KIT), 76344 Eggenstein-Leopoldshafen, Germany E-mail: christof.woell@kit.edu

1. Achromatic Objectives: These are standard objectives that correct for chromatic aberration, enhancing color accuracy in the image.

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Choosing the right type of objective lens depends on the specific requirements of the microscopy application, including the type of specimen, desired level of detail, and any specialized techniques being employed.

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4. Field of View: This specification indicates the area of the specimen that can be observed at a specific level of magnification. It's crucial for understanding the scope of what can be viewed.

2. Numerical Aperture (NA): A higher NA indicates better resolution and light-gathering capabilities, which can result in clearer and more detailed images.

a Beijing Key Laboratory of Bio-inspired Energy Materials and Devices, School of Space and Environment, Beihang University, Beijing, China

7. Phase Contrast Objectives: These are specially designed for phase contrast microscopy, a technique used to visualize transparent or low-contrast specimens without the need for staining.

c Leibniz Institute of Photonic Technology (IPHT), Albert-Einstein-Str. 9, D-07745 Jena, Germany E-mail: thomas.mayerhoefer@uni-jena.de

8. Darkfield Objectives: These objectives are optimized for darkfield microscopy, a technique used to observe specimens against a dark background, enhancing contrast for certain types of samples.

C. Yang, W. Wang, A. Nefedov, Y. Wang, T. G. Mayerhöfer and C. Wöll, Phys. Chem. Chem. Phys., 2020, 22, 17129 DOI: 10.1039/D0CP02399J

Objective lenses are typically labeled with two numbers, such as 10x/0.25. The first number represents the magnification, indicating that the lens magnifies the specimen by a factor of 10. The second number is the numerical aperture (NA), which signifies the lens's ability to gather light. This combination of magnification and numerical aperture is crucial in determining the level of detail and clarity that can be achieved when examining specimens under a microscope.

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14. Ultraviolet (UV) Radiation Objectives: Objective lenses tailored for the ultraviolet (UV) radiation range are crafted for brightfield microscopy and find applicability in laser-based tasks. These UV objectives boast features like infinity correction, long working distance, and a Plan Apochromat design. They excel in performance specifically within the ultraviolet spectrum (266nm) and also maintain high-quality imaging for visible wavelengths.

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3. Fluorescence Objectives: These specialized lenses are optimized for fluorescent microscopy. They enable the observation of specimens labeled with fluorescent markers, which emit light of a specific wavelength when illuminated.

2. Plan Objectives: Designed for flat-field microscopy, these objectives ensure a sharp focus across the entire visual field, reducing distortion at the edges.

The interaction of light with matter at surfaces of dielectrics strongly depends on polarization. Here, we present the first infrared spectroscopic evidence for significant polarization effects in the spectroscopic detection of adsorbate vibrational frequencies. In addition to much larger peak intensities for p-polarized light relative to s-polarization, a small but distinct blue shift was identified for CO adsorbed at the surfaces of two prototype dielectric substrates, CeO2(111) and CaCO3(10.4). A simulation using a layer model yields very good agreement with experiment.

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4. High-Resolution Objectives: These offer exceptionally high levels of detail and are ideal for applications requiring precise imaging, such as in medical or scientific research.

By understanding these specifications, users can make informed decisions about which objective lens is best suited for their specific microscopy needs. This ensures that they can achieve the highest level of detail and clarity in their observations.

A scanning objective in microscopy refers to a specific type of objective lens used to observe specimens. It is characterized by a low magnification level, typically between 2x and 4x, and is designed to provide a wide field of view. Scanning objectives are commonly used for initial specimen location and overview. They allow for quick scanning of a large area to locate regions of interest before switching to higher magnification objectives for detailed examination. This type of objective is particularly useful in tasks where a broad perspective is needed before zooming in for more precise observation.

High power objective lenses in microscopes typically have magnifications ranging from 40x to 100x. These lenses are used for detailed examination of specimens and provide high levels of magnification, allowing for close-up views of fine structures and cellular details. Keep in mind that the actual magnification will also depend on the eyepiece being used in conjunction with the high-power objective. For example, if you're using a 10x eyepiece with a 40x objective, the total magnification will be 400x.

The primary function of objective lenses in microscopy is to capture light emitted or reflected by the specimen. They then focus this light to form an enlarged image, which can be further magnified by the eyepiece lens. By adjusting the objective lens, users can achieve different levels of magnification, allowing for detailed examination of minute structures.

3. Working Distance: This is the distance required between the objective lens and the specimen to create an in-focus image. It's an important consideration, especially in applications where space is limited, or when using specialized accessories.

A microscope objective lens is a fundamental component of a microscope responsible for gathering and magnifying the image of a specimen. Positioned in close proximity to the specimen, it plays a crucial role in determining the quality and clarity of the final magnified image.

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9. Metallurgical Objectives: Unlike standard microscope lenses, it has a longer working distance, is designed for an inverted microscope configuration, and often boasts a high numerical aperture for better resolution. These features make it particularly effective for analyzing opaque, irregularly shaped metal specimens in fields like materials science and metallurgy.

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1. Magnification Range: This determines the range of magnification levels the lens can achieve, allowing for versatility in examining different types of specimens.

5. Correction Type: Depending on the type of microscope and the specific application, one may choose from achromatic, plan, or specialized objectives. Each type is optimized for different imaging conditions.

11. Stereo Microscope Auxiliary Objectives: Stereo microscope auxiliary objectives are supplementary lenses used to alter the magnification and working distance of a stereo microscope. They are designed to be easily interchangeable, allowing users to adapt the microscope's capabilities for different tasks. These objectives can provide additional magnification for closer inspection of specimens or extend the working distance to accommodate larger objects. They play a crucial role in enhancing the versatility and functionality of stereo microscopes in various fields such as biology, electronics, and precision manufacturing.

13. Near-Ultraviolet Radiation (NUV) Objectives: Objective lenses designed for the near-ultraviolet (NUV) radiation range are tailored for brightfield microscopy, making them well-suited for laser applications. These NUV objectives possess characteristics such as Plan Apochromat design, long working distance, and infinity correction. Specifically optimized for wavelengths from near-ultraviolet (355nm) to visible light, they offer high-performance imaging in this spectral range. Additionally, high-resolution NUV objectives are also available for specialized applications.

5. Oil Immersion Objectives: These objectives are designed to work with a layer of immersion oil between the lens and the specimen. This reduces refraction and increases numerical aperture, allowing for higher resolution images.

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