Products Home / Optical Systems / Objective Lenses, Scan Lenses, and Tube Lenses / Imaging Microscope Objectives, DryImaging Microscope Objectives, Dry
- Infinity-Corrected Microscope Objectives for UV, Visible, and NIR
- Designed for Use with Air between Objective and Sample or Cover Glass
- Magnifications Ranging from 1X to 100X
- Plan Achromat, Plan Apochromat, and Plan Fluorite Designs
RMS4X
4X Plan Achromat
for Visible Wavelengths
TL1X-SAP
1X Super Apochromat
for 420 to 700 nm
N60X-PF
60X Plan Fluorite
for UV to NIR Wavelengths
MY10X-803
10X Plan Apochromat
for 480 to 1800 nm
LMUL-50X-UVB
50X Plan Apochromat
for 240 to 360 nm
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| Objective Lens Selection Guide |
|---|
| Objectives |
| Super Apochromatic Microscope Objectives Microscopy Objectives, Dry Microscopy Objectives, Oil Immersion Physiology Objectives, Water Dipping or Immersion Phase Contrast Objectives Long Working Distance Objectives Reflective Microscopy Objectives UV Focusing Objectives VIS and NIR Focusing Objectives |
| Scan Lenses and Tube Lenses |
| Scan Lenses F-Theta Scan Lenses Infinity-Corrected Tube Lenses |
Did You Know?
Multiple optical elements, including the microscope objective, tube lens, and eyepieces, together define the magnification of a system. See the Magnification & FOV tab to learn more.
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Example of a Dry Objective Design
(See Objective Tutorial Tab for More Information About Microscope Objective Types)
Thorlabs offers dry objectives made in house, as well as objectives from Olympus, Nikon, and Mitutoyo. Plan achromat, plan fluorite (also called plan semi-apochromat or plan fluor), plan apochromat, and super apochromat designs are available. For details about the differences between these types of objectives, please see the Objective Tutorial tab above.
When choosing a microscope objective, it is important to keep in mind that objectives are often designed to integrate with a particular manufacturer's microscopes. Before interchanging objectives, be sure to check the design tube lens focal length and the threading type of the objectives. A full list of specifications for each objective can be found in the Specs tab above. Please note that the performance of each objective may vary from the engraved specifications when integrated with components and systems from different manufacturers. See the Magnification and FOV tab for more information.
Our selection of dry objectives can be used in applications from microscopy to fiber coupling and includes options optimized for use at wavelengths from the UV to the NIR. For information on recommended applications for specific objectives, see below.
All objectives featured on this page are compatible with our microscope nosepiece modules for DIY Cerna® systems, which accept RMS, M25 x 0.75, or M32 x 0.75 objective threading. Parfocal lengths can be matched by using our parfocal length extenders. The Olympus microscope objectives can be mounted directly to our fiber launch systems, or mounted into our 30 mm cage system using the CP42(/M) RMS-threaded cage plate, which is also post mountable. They can also be mounted to any of our multi-axis platforms or translation stages using an HCS013 RMS mount. Please note that the multi-axis platforms and translation stages need a 3 mm wide central keyway for the HCS013 RMS mount.
To use these objectives with a different thread standard, please see our microscope objective thread adapters.
| 1X - 7.5X Objective Specifications | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Magnificationa | 1Xb | 2X | 4X | 5X | 7.5X | ||||
| Manufacturer | Thorlabs | Thorlabs | Thorlabs | Olympus | Nikon | Mitutoyo | Mitutoyo | ||
| Item # | TL1X-SAP | TL2X-SAP | TL4X-SAP | RMS4X | RMS4X-PF | N4X-PF | MY5X-802 | MY5X-822 | MY7X-807 |
| Objective Class | Super Apochromat | Super Apochromat | Super Apochromat | Plan Achromat | Plan Fluorite | Plan Fluorite | Plan Apochromat | ||
| Numerical Aperture (NA) | 0.03 | 0.10 | 0.20 | 0.10 | 0.13 | 0.13 | 0.14 | 0.14 | 0.21 |
| Entrance Pupil Diameterc | 12 mm | 20 mm | 20 mm | 9.0 mm | 11.7 mm | 13 mm | 11.2 mm | 11.2 mm | 11.2 mm |
| Effective Focal Length (EFL) | 200 mm | 100 mm | 50 mm | 45 mm | 45 mm | 50 mm | 40 mm | 40 mm | 26.7 mm |
| Working Distance | 8.0 mm | 56.3 mm | 17.0 mm | 18.5 mm | 17 mm | 17.2 mm | 34.0 mm | 37.5 mm | 35.0 mm |
| Parfocal Length | 95.0 mm | 95.0 mm | 60.0 mm | 45.06 mm | 45.06 mm | 60 mm | 95 mm | 95 mm | 95 mm |
| Design Tube Lens Focal Length | 200 mm | 200 mm | 200 mm | 180 mm | 180 mm | 200 mm | 200 mm | 200 mm | 200 mm |
| Coverglass Thickness | 0 - 5.0 mm | 0 - 5.0 mm | 0 - 5.0 mm | 0 - 0.17 mm | 0 - 0.17 mm | 0 - 0.17 mm | 0 mm | 0 mm | 0 mm |
| Diameter | 32.6 mm (Without Wave Plate) |
30.5 mm | 30.5 mm | 24.0 mm | 24.0 mm | 30.0 mm | 34.0 mm | 34.0 mm | 34.0 mm |
| 34.5 mm (With Wave Plate) |
|||||||||
| Length | 85.5 mm (Without Wave Plate) |
43.5 mm | 46.4 mm | 30.9 mm | 32.4 mm | 46.6 mm | 66.0 mm | 62.5 mm | 65.0 mm |
| 90.6 mm (With Wave Plate) |
|||||||||
| Threading | M25 x 0.75 | M25 x 0.75 | M25 x 0.75 | RMS | RMS | M25 x 0.75 | M26 x 0.706 | M26 x 0.706 | M26 x 0.706 |
| Threading Depth | 3.8 mm | 3.2 mm | 3.6 mm | 4.5 mm | 4.5 mm | 3.6 mm | 5.0 mm | 5.0 mm | 5.0 mm |
| Wavelength Range | 420 - 700 nm | 350 - 700 nm | 350 - 700 nm | Visible | Visible to NIR | UV to NIR | 436 - 656 nm | 480 - 1800 nm | 436 - 656 nm |
| Antireflection Coating | Ravg < 0.5% (420 - 700 nm) |
Ravg < 0.5% (350 - 700 nm) |
Ravg < 0.5% (350 - 700 nm) |
Proprietary | Proprietary | Proprietary | Proprietary | Proprietary | Proprietary |
| Field of View | Ø22 mm | Ø11 mm | Ø5.5 mm | Ø5.5 mm | Ø6.625 mm | Ø6.25 mm | Ø4.8 mm | Ø4.8 mm | Ø3.2 mm |
| Optical Field Number | 22 | 22 | 22 | 22 | 26.5 | 25 | 24 | 24 | 24 |
| Coverslip Correction Collar | No | No | No | No | No | No | No | No | No |
| 10X Objective Specifications | |||||||
|---|---|---|---|---|---|---|---|
| Magnificationa | 10X | ||||||
| Manufacturer | Thorlabs | Olympus | Nikon | Mitutoyo | |||
| Item # | LMUL-10X-UVB | TL10X-2P | RMS10X | RMS10X-PF | N10X-PF | MY10X-823 | MY10X-803 |
| Objective Class | Achromat | Super Apochromat | Plan Achromat | Plan Fluorite | Plan Fluorite | Plan Apochromat | Plan Apochromat |
| Numerical Aperture (NA) | 0.25 | 0.50 | 0.25 | 0.3 | 0.3 | 0.26 | 0.28 |
| Entrance Pupil Diameterb | 10.0 mm | 20 mm | 9.0 mm | 10.8 mm | 12 mm | 10.4 mm | 11.2 mm |
| Effective Focal Length (EFL) | 20 mm | 20 mm | 18 mm | 18 mm | 20 mm | 20 mm | 20 mm |
| Working Distance | 20.0 mm | 7.77 mm | 10.6 mm | 10 mm | 20 mm | 30.5 mm | 34 mm |
| Parfocal Length | 95.0 mm | 95.0 mm | 45.06 mm | 45.06 mm | 60 mm | 95 mm | 95 mm |
| Design Tube Lens Focal Length | 200 mm | 200 mm | 180 mm | 180 mm | 200 mm | 200 mm | 200 mm |
| Cover Glass Thickness | 0 mm | 0 - 2.6 mm | 0 - 0.17 mm | 0 - 0.17 mm | 0.17 | 0 mm | 0 mm |
| Diameter | 34.0 mm | 40.6 mm | 24.0 mm | 24.0 mm | 30.0 mm | 34.0 mm | 34.0 mm |
| Length | 80.0 mm | 90.4 mm | 38.8 mm | 39.4 mm | 48.7 mm | 68.5 mm | 66.0 mm |
| Threading | M26 x 0.706 | M32 x 0.75 | RMS | RMS | M25 x 0.75 | M26 x 0.706 | M26 x 0.706 |
| Threading Depth | 5.0 mm | 3.2 mm | 4.5 mm | 4.5 mm | 5.0 mm | 5.0 mm | 5.0 mm |
| Wavelength Range | 240 - 360 nm | 400 - 1300 nm | Visible | Visible to NIR | UV to NIR | 480 - 1800 nm | 436 - 656 nm |
| Antireflection Coating | <1.5% per Surface (240 - 360 nm) |
Rabs < 2.5% (400 - 450 nm) Rabs < 1.75% (450 - 1300 nm) |
Proprietary | Proprietary | Proprietary | Proprietary | Proprietary |
| Field of View | Ø2.4 mm | Ø2.2 mm | Ø2.2 mm | Ø2.65 mm | Ø2.5 mm | Ø2.4 mm | Ø2.4 mm |
| Optical Field Number | 24 | 22 | 22 | 26.5 | 25 | 24 | 24 |
| Coverslip Correction Collar | No | Yes | No | No | No | No | No |
| 20X Objective Specifications | ||||||
|---|---|---|---|---|---|---|
| Magnificationa | 20X | |||||
| Manufacturer | Thorlabs | Olympus | Nikon | Mitutoyo | ||
| Item # | LMUL-20X-UVB | RMS20X | RMS20X-PF | N20X-PF | MY20X-804 | MY20X-824 |
| Objective Class | Achromat | Plan Achromat | Plan Fluorite | Plan Fluorite | Plan Apochromat | Plan Apochromat |
| Numerical Aperture (NA) | 0.36 | 0.4 | 0.5 | 0.5 | 0.42 | 0.40 |
| Entrance Pupil Diameterb | 7.2 mm | 7.2 mm | 9.0 mm | 10 mm | 8.4 mm | 8.0 mm |
| Effective Focal Length (EFL) | 10 mm | 9 mm | 9 mm | 10 mm | 10 mm | 10 mm |
| Working Distance | 15.3 mm | 1.2 mm | 2.1 mm | 2.1 mm | 20.0 | 20.0 mm |
| Parfocal Length | 95.0 mm | 45.06 mm | 45.06 mm | 60 mm | 95.0 mm | 95.0 mm |
| Design Tube Lens Focal Length | 200 mm | 180 mm | 180 mm | 200 mm | 200 mm | 200 mm |
| Cover Glass Thickness | 0 mm | 0.17 mm | 0.17 mm | 0.17 mm | 0 mm | 0 mm |
| Diameter | 34.0 mm | 24.0 mm | 26.0 mm | 28.0 mm | 34.0 mm | 34.0 mm |
| Length | 84.7 mm | 48.5 mm | 47.3 mm | 63.5 mm | 80.0 mm | 80.0 mm |
| Threading | M26 x 0.706 | RMS | RMS | M25 x 0.75 | M26 x 0.706 | M26 x 0.706 |
| Threading Depth | 5.0 mm | 4.8 mm | 4.5 mm | 5.0 mm | 5.0 mm | 5.0 mm |
| Wavelength Range | 240 - 360 nm | Visible | Visible to NIR | UV to NIR | 436 - 656 nm | 480 - 1800 nm |
| Antireflection Coating | <1.5% per Surface (240 - 360 nm) |
Proprietary | Proprietary | Proprietary | Proprietary | Proprietary |
| Field of View | Ø1.2 mm | Ø1.1 mm | Ø1.325 mm | Proprietary | Ø1.2 mm | Ø1.2 mm |
| Optical Field Number | 24 | 22 | 26.5 | Proprietary | 24 | 24 |
| Coverslip Correction Collar | No | No | No | No | No | No |
| 40X - 100X Objective Specifications | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Magnificationa | 40X | 50X | 60X | 100X | |||||
| Manufacturer | Olympus | Nikon | Thorlabs | Mitutoyo | Olympus | Nikon | Mitutoyo | ||
| Item # | RMS40X | RMS40X-PF | N40X-PF | LMUL-50X-UVB | MY50X-805 | MY50X-825 | RMS60X-PFC | N60X-PF | MY100X-806 |
| Objective Class | Plan Achromat | Plan Fluorite | Plan Fluorite | Achromat | Plan Apochromat | Plan Apochromat | Plan Fluorite | Plan Fluorite | Plan Apochromat |
| Numerical Aperture (NA) | 0.65 | 0.75 | 0.75 | 0.42 | 0.55 | 0.42 | 0.9 | 0.85 | 0.70 |
| Entrance Pupil Diameterb | 5.8 mm | 6.8 mm | 7.5 mm | 3.4 mm | 4.4 mm | 3.4 mm | 5.4 mm | 5.7 mm | 2.8 mm |
| Effective Focal Length (EFL) | 4.5 mm | 4.5 mm | 5.0 mm | 4 mm | 4.0 mm | 4.0 mm | 3.0 mm | 3.3 mm | 2.0 mm |
| Working Distance | 0.6 mm | 0.51 mm | 0.66 mm | 12.0 mm | 13.0 mm | 17.0 mm | 0.2 mm | 0.31 - 0.4 mm | 6.0 mm |
| Parfocal Length | 45.06 mm | 45.06 mm | 60 mm | 95.0 mm | 95 mm | 95 mm | 45.06 mm | 60 mm | 95 mm |
| Design Tube Lens Focal Length | 180 mm | 180 mm | 200 mm | 200 mm | 200 mm | 200 mm | 180 mm | 200 mm | 200 mm |
| Cover Glass Thickness | 0.17 mm | 0.17 mm | 0.17 mm | 0 mm | 0 mm | 0 mm | 0.11 - 0.23 mm | 0.11 - 0.23 mm | 0 mm |
| Diameter | 24.0 mm | 26.0 mm | 30.0 mm | 34.0 mm | 34.0 mm | 34.0 mm | 31.0 mm | 31.4 mm | 34.0 mm |
| Length | 48.8 mm | 48.9 mm | 59.1 mm | 88.0 mm | 87.0 mm | 82.4 mm | 49.4 mm | 65.0 mm | 94.0 mm |
| Threading | RMS | RMS | M25 x 0.75 | M26 x 0.706 | M26 x 0.706 | M26 x 0.706 | RMS | M25 x 0.75 | M26 x 0.706 |
| Threading Depth | 4.5 mm | 4.5 mm | 5.1 mm | 5.0 mm | 5.0 mm | 5.0 mm | 4.7 mm | 5.0 mm | 5.0 mm |
| Wavelength Range | Visible | Visible to NIR | UV to NIR | 240 - 360 nm | 436 - 656 nm | 480 - 1800 nm | Visible to NIR | UV to NIR | 436 - 656 nm |
| Antireflection Coating | Proprietary | Proprietary | Proprietary | <1.5% per Surface (240 - 360 nm) |
Proprietary | Proprietary | Proprietary | Proprietary | Proprietary |
| Field of View | Ø0.55 mm | Ø0.663 mm | Ø0.625 mm | Ø0.48 mm | Ø0.48 mm | Ø0.48 mm | Ø0.44 mm | Ø0.42 mm | Ø0.24 mm |
| Optical Field Number | 22 | 26.5 | 25 | 24 | 24 | 24 | 26.5 | 25 | 24 |
| Coverslip Correction Collar | No | No | No | No | No | No | Yes | Yes | No |
Objective Identification
Note: These microscope objectives serve only as examples. The format of the engraved specifications will vary between objectives and manufacturers.
Types of Objectives
We offer our own objectives as well as ones from other manufacturers like Nikon, Olympus, and Mitutoyo. This guide describes the features and benefits of each type of objective.
Dry or Oil-Immersion Objectives
This designation refers to the medium that should be present between the front of the objective and the cover glass of the microscope slide. Dry objectives are designed to work best with an air gap between the objective and the specimen, while oil-immersion objectives require the use of a drop of immersion oil (such as MOIL-30) between and in contact with the front lens of the objective and the cover glass. Oil immersion is required in order to achieve numerical apertures greater than 1.0. Note that if an oil immersion objective is used without the oil present, the image quality will be very low. Our oil-immersion objectives are presented here.
Super Apochromatic Objectives
Super apochromatic objectives offer chromatic and spherical aberration correction in the visible range and produce a flat field of focus in a variety of imaging modalities without introducing vignetting.
Plan Achromat and Plan Apochromat Objectives
"Plan" designates that these objectives produce a flat image across the field of view. "Achromat" refers to the correction for chromatic aberration featured in the lens design. These objectives have chromatic aberration correction for two wavelengths and spherical aberration correction at one wavelength. Plan achromats produce their best images for green light. The apochromat objectives on this page have chromatic aberration correction for three wavelengths and spherical aberration correction at two wavelengths. In white light, the plan achromats give satisfactory images for color photomicrography, but the results are not as good as objectives that feature better correction, such as plan apochromats or the plan fluorite objectives below.
Plan Fluorite Objectives
Plan fluorite objectives, also referred to as plan semi-apochromats, plan fluorescence objectives, or plan fluors, also produce a flat image across the field of view. Plan fluorite objectives are corrected for chromatic aberrations at two to four wavelengths and spherical aberrations at three to four wavelengths. In addition to being corrected for more wavelengths, plan fluorite objectives generally offer reduced aberrations between the design wavelengths relative to plan achromats. These objectives also work well for color photomicrography.
| Magnification Color Codes |
|---|
| Immersion Media Color Codes |
|---|
Glossary of Terms
Magnification
The magnification of an objective is the lens tube focal length (L) divided by the objective's focal length (F):
M = L / F .
The total magnification of the system is the magnification of the objective multiplied by the magnification of the eyepiece or camera tube. The specified magnification on the microscope objective housing is accurate as long as the objective is used with a compatible tube lens focal length.
Numerical Aperture (NA)
Numerical aperture, a measure of the acceptance angle of an objective, is a dimensionless quantity. It is commonly expressed as
NA = ni × sinθa
where θa is the maximum 1/2 acceptance angle of the objective, and ni is the index of refraction of the immersion medium. This medium is typically air, but may also be water, oil, or other substances.
Parfocal Length
Also referred to as the parfocal distance, this is the length from the top of the objective (at the base of the mounting thread) to the bottom of the cover glass (or top of the specimen in the case of objectives that are intended to be used without a cover glass). For instances in which the parfocal length needs to be increased, parfocal length extenders are available.
Working Distance
This is the distance between the front element of the objective and the specimen, depending on the design of the objective. The cover glass thickness specification engraved on the objective designates whether a cover glass should be used.
Click to Enlarge
This graph shows the effect of a cover slip on image quality at 632.8 nm.
Field Number
The field number corresponds to the size of the field of view (in millimeters) multiplied by the objective's magnification.
FN = Field of View Diameter × Magnification
Correction Collar (Ring) and Cover Glass Thickness
A typical coverslip (cover glass) is designed to be 0.17 mm thick, but due to variance in the manufacturing process the actual thickness may be different. The correction collar present on select objectives is used to compensate for coverslips of different thickness by adjusting the relative position of internal optical elements. Note that many objectives do not have a variable coverslip correction (for example, an objective could be designed for use with only a standard 0.17 mm thick coverglass), in which case the objectives have no correction collar.
The graph to the right shows the magnitude of spherical aberration versus the thickness of the coverslip used, for 632.8 nm light. For the typical coverslip thickness of 0.17 mm, the spherical aberration caused by the coverslip does not exceed the diffraction-limited aberration for objectives with NA up to 0.40.
When viewing an image with a camera, the system magnification is the product of the objective and camera tube magnifications. When viewing an image with trinoculars, the system magnification is the product of the objective and eyepiece magnifications.
| Manufacturer | Tube Lens Focal Length |
|---|---|
| Leica | f = 200 mm |
| Mitutoyo | f = 200 mm |
| Nikon | f = 200 mm |
| Olympus | f = 180 mm |
| Thorlabs | f = 200 mm |
| Zeiss | f = 165 mm |
Magnification and Sample Area Calculations
Magnification
The magnification of a system is the multiplicative product of the magnification of each optical element in the system. Optical elements that produce magnification include objectives, camera tubes, and trinocular eyepieces, as shown in the drawing to the right. It is important to note that the magnification quoted in these products' specifications is usually only valid when all optical elements are made by the same manufacturer. If this is not the case, then the magnification of the system can still be calculated, but an effective objective magnification should be calculated first, as described below.
To adapt the examples shown here to your own microscope, please use our Magnification and FOV Calculator, which is available for download by clicking on the red button above. Note the calculator is an Excel spreadsheet that uses macros. In order to use the calculator, macros must be enabled. To enable macros, click the "Enable Content" button in the yellow message bar upon opening the file.
Example 1: Camera Magnification
When imaging a sample with a camera, the image is magnified by the objective and the camera tube. If using a 20X Nikon objective and a 0.75X Nikon camera tube, then the image at the camera has 20X × 0.75X = 15X magnification.
Example 2: Trinocular Magnification
When imaging a sample through trinoculars, the image is magnified by the objective and the eyepieces in the trinoculars. If using a 20X Nikon objective and Nikon trinoculars with 10X eyepieces, then the image at the eyepieces has 20X × 10X = 200X magnification. Note that the image at the eyepieces does not pass through the camera tube, as shown by the drawing to the right.
Using an Objective with a Microscope from a Different Manufacturer
Magnification is not a fundamental value: it is a derived value, calculated by assuming a specific tube lens focal length. Each microscope manufacturer has adopted a different focal length for their tube lens, as shown by the table to the right. Hence, when combining optical elements from different manufacturers, it is necessary to calculate an effective magnification for the objective, which is then used to calculate the magnification of the system.
The effective magnification of an objective is given by Equation 1:
 |
(Eq. 1) |
Here, the Design Magnification is the magnification printed on the objective, fTube Lens in Microscope is the focal length of the tube lens in the microscope you are using, and fDesign Tube Lens of Objective is the tube lens focal length that the objective manufacturer used to calculate the Design Magnification. These focal lengths are given by the table to the right.
Note that Leica, Mitutoyo, Nikon, and Thorlabs use the same tube lens focal length; if combining elements from any of these manufacturers, no conversion is needed. Once the effective objective magnification is calculated, the magnification of the system can be calculated as before.
Example 3: Trinocular Magnification (Different Manufacturers)
When imaging a sample through trinoculars, the image is magnified by the objective and the eyepieces in the trinoculars. This example will use a 20X Olympus objective and Nikon trinoculars with 10X eyepieces.
Following Equation 1 and the table to the right, we calculate the effective magnification of an Olympus objective in a Nikon microscope:
 |
The effective magnification of the Olympus objective is 22.2X and the trinoculars have 10X eyepieces, so the image at the eyepieces has 22.2X × 10X = 222X magnification.
Sample Area When Imaged on a Camera
When imaging a sample with a camera, the dimensions of the sample area are determined by the dimensions of the camera sensor and the system magnification, as shown by Equation 2.
 |
(Eq. 2) |
The camera sensor dimensions can be obtained from the manufacturer, while the system magnification is the multiplicative product of the objective magnification and the camera tube magnification (see Example 1). If needed, the objective magnification can be adjusted as shown in Example 3.
As the magnification increases, the resolution improves, but the field of view also decreases. The dependence of the field of view on magnification is shown in the schematic to the right.
Example 4: Sample Area
The dimensions of the camera sensor in Thorlabs' 1501M-USB Scientific Camera are 8.98 mm × 6.71 mm. If this camera is used with the Nikon objective and trinoculars from Example 1, which have a system magnification of 15X, then the image area is:
 |
Sample Area Examples
The images of a mouse kidney below were all acquired using the same objective and the same camera. However, the camera tubes used were different. Read from left to right, they demonstrate that decreasing the camera tube magnification enlarges the field of view at the expense of the size of the details in the image.
| Posted Comments: | |
Ludo Angot
(posted 2020-09-16 04:38:41.34) Hello, the schematic of your TTL200 recommends a given distance between the objective lens entrance pupil plane and the tube lens. Could you please provide the location of the pupil plane for your TL2X-SAP and TL4X-SAP lenses (for example specified as the distance from the flange)? I'm not sure if the zemax file provides this information but I don't have this software. The pupil distance will also be useful to use these lenses with other tube lenses and to draw more realistic optical diagrams. Thanks! YLohia
(posted 2020-09-28 08:35:51.0) Hello, thank you for contacting Thorlabs. The pupil on the TL4X and the TL2X are both the first lens surface, so roughly on the flange shoulder. The distance required between the objective and tube lens is not a hard requirement. For example, our TTL200-A can have a pupil distance of 70-140 mm without vignetting or aberrations. user
(posted 2019-09-29 20:38:24.053) Hi, I just buy RMS20X for expanding the laser beam (632nm, HeNe Laser). The strange interference fringes (curved and light) happen after passing through the objective lens! I use the camera to observe and when I move the camera the fringes also change. Before enter the objective lens are just laser source and two mirrors. So could you tell me the reason? Thanks. YLohia
(posted 2019-10-01 09:54:02.0) Hello, thank you for contacting Thorlabs. Based on our direct troubleshooting, it has been determined that the interference fringes were being caused by the etalon effect from the thin protective (removable) window on your camera. Please also note that your 6.8mm input diameter beam needs to be carefully aligned to the center of the relatively small (7.2mm) entrance aperture of the RMS20X to prevent other beam defects. r07941046
(posted 2018-12-24 22:47:26.263) Are RMS60X-PFC and N60X-PF suitable for 1550 nm wavelength? Thank you. nbayconich
(posted 2018-12-26 01:08:54.0) Thank you for contacting Thorlabs. Transmission at 1550nm will be relatively low for both objectives and may not be suitable. Since not all of our vendors provide transmission plots to share I will reach out to you directly to discuss the ideal working range for these products. deokkihong
(posted 2018-07-30 22:48:15.767) Hi, I want to analyse a system including objective lens with opitics program like 'Code five' or 'Zemax' .
Is there any supplement data of RMS10X and RMS20X for 'Geometric optics program'? YLohia
(posted 2018-07-31 09:56:33.0) Hello, thank you for contacting Thorlabs. These two objective lenses are made by Olympus and, unfortunately, they do not offer Zemax (or other ray tracing) files. marc.miousset
(posted 2018-04-02 08:40:00.973) Hi,
Please, I need mount RSM10X, on SMIL1 or other, and they trhead, does'n work.
What ring works in the catalog Thorlabs.
Thanks
Have nice day
Marc YLohia
(posted 2018-04-03 03:27:06.0) Hello Marc, thank you for leaving feedback on our website. I wasn't able to find anything in our catalog with the part number SMIL1 -- are you referring to SM1L10? If that is the case, you can use the SM1A3 or SM1A3TS adapters to mate the RMS10X to any of our internally SM1-threaded components (for e.g., SM1L10). vinithamr
(posted 2017-06-12 19:56:18.133) hello, I want to couple free space laser beam of diameter 1mm into optical fiber P1-780PM-FC(NA 0.12). How to choose the objective lens for that especially NA and EFL. Pls help. tfrisch
(posted 2017-06-26 02:38:06.0) Hello, thank you for contacting Thorlabs. I will reach out to you about both geometric approximations for fiber coupling as well as equations needed to match the diffraction limited spot size to the mode field diameter. In the latter, I will need to know the wavelength of the source. libaikui
(posted 2017-02-10 17:19:50.68) Can the objectives be used in magnetic field ~1T? Is there any effect on the position of the spot, transmission, etc? tfrisch
(posted 2017-02-16 11:49:16.0) Hello, thank you for contacting Thorlabs. We don't have a way to test these objectives under various magnetic fields, but I will reach out to you directly about your application. naveedullah1984
(posted 2016-10-07 10:54:40.953) How can I calculate the spot size for an objective lens. I am using a collimated 635 nm Laser light. jlow
(posted 2016-10-07 04:42:44.0) Response from Jeremy at Thorlabs: The focused spot size is going to be dependent on the input beam diameter and how Gaussian your input beam is. For a Gaussian beam (M^2=1), you can use the diffraction limited spot size formula (4*λ*f)/(pi*input beam size) to estimate the spot size. egorglad
(posted 2016-09-27 07:33:55.527) Hello. Please need help. I need datashet on a RMS20X. I need data such as dispersion of lens, lenses type, Coating of lens. It's need for calculate my optical systen. jlow
(posted 2016-09-29 04:17:21.0) Response from Jeremy at Thorlabs: I will contact you directly about this. user
(posted 2016-09-26 16:52:05.52) Question to tfrisch Posted Date:2016-09-01:
In overview tab, you mention "They are designed to have high transmission, particularly at UV wavelengths"
give us a hint on how we should understand the description? tcampbell
(posted 2016-10-12 08:48:43.0) Response from Tim at Thorlabs: Thank you for your feedback. These objectives have high transmission in the near UV, visible, and near IR wavelength ranges. We have updated the web to be more clear about this. user
(posted 2016-08-26 18:46:41.743) Hello,
I am looking for a microscope objective to perform spatial filtering. This will be used in conjunction with a 325nm laser. The Nikon N40X-PF, infinity corrected seems to be a suitable option as it is designed for UV applications but I cannot find its transmittance at my wavelength of interest.
thank you tfrisch
(posted 2016-09-01 10:23:07.0) Hello, thank you for contacting Thorlabs. Unfortunately, Nikon has not shared transmission data with us. We do give UV transmission curves for our Microspot Objectives here:
https://www.thorlabs.com/newgrouppage9.cfm?objectgroup_id=3271&tabname=Graphs stefano.minardi
(posted 2016-02-23 14:48:52.153) Dear Sirs,
I'm planning to use the objective RMS40X to focus a 10W CW laser beam at a wavelength of 1550 nm. Is the damage threshold of the objective high enough for this application?
Thank you and best regards
Stefano Minardi besembeson
(posted 2016-03-08 01:46:43.0) Response from Bweh at Thorlabs USA: 10W is too high for these objectives. Olympus recommends limiting the power to under 100mW for collimated light. user
(posted 2015-12-17 11:43:32.007) Hello, does any one have experience placing these objectives into a cryostat (LN2, 77 K)? besembeson
(posted 2015-12-18 11:58:31.0) Response from Bweh at Thorlabs USA: We don't have test data on these objectives under such conditions at this time. I will check if Olympus and Nikon can provide this feedback. gtn75
(posted 2015-11-19 19:52:07.67) I want to know where are the principal planes of this objective. besembeson
(posted 2015-11-20 02:25:21.0) Response from Bweh at Thorlabs USA: The effective focal length is 20mm, and the working distance of course is 16mm. Nikon doesn't provide the back focal length of the objective. jesmondhong
(posted 2015-03-25 00:12:16.623) The working distance of the infinity corrected objective is the distance from the sample to the lens. what about the focal length? Is the focal length measured from the lens as well? besembeson
(posted 2015-04-21 07:07:29.0) Response from Bweh at Thorlabs USA: Not really. The working distance is from the surface of the objective. The focal length is from a lens position inside the objective housing, useful for magnification, spacing constraints and numerical aperture calculations. user
(posted 2015-03-09 15:02:07.91) Hello, I am interested in the Olympus RMS4X but I need additional information on the field of view, is it possible to get it ?
Do you have the Zemax "black-box" design for this objective ?
Thank you in advance.
Olivier besembeson
(posted 2015-03-26 01:14:17.0) Response from Bweh at Thorlabs USA: Olympus doesn't provide such models for these objectives and we don't have a black box design. If there is any specific property you are interested in for this objective, let me know. c.j.lee
(posted 2015-03-06 11:35:50.093) Hi,
We are making a Raman microscope using the Olympus objectives (4x and 10x). For quite some time, we were trying to eliminate what appeared to be a large spurious signal. On changing the objectives from the ones we purchased to a Leica objective from an old microscope, suddenly, the signal noise reduced substantially. Our conclusion was that the objectives (including the Leica) are emitting autoflourescence.
Do you have any recommended objectives for Raman spectroscopy? Ones that are known to use pure fused silica, rather than doped glasses? besembeson
(posted 2015-03-25 05:04:35.0) Autofluorescence is possible depending on the excitation wavelengths in your application. The RMS4X and RMS10X have low NA, which may not be suitable for Raman applications, where collection efficiency, spatial resolution and depth of focus all become important. Optimal design is a reflective objective which eliminates all chromatic aberrations with excellent spatial resolution in a broad spectral range. You may consider one of our series of Schwarzschild designed reflective objectives, such as the LMM-40X-UVV which can be found at the following link: http://www.thorlabs.de/newgrouppage9.cfm?objectgroup_ID=6933. simon.stehle
(posted 2015-02-13 13:51:44.64) Dear Sir or Madam,
we intend to use your "RMS20x" to focus the Laser Light (532 nm, cw).
Can you give a statement about the maximum Power acceptable for the RMS20X?
Thanks, Simon. besembeson
(posted 2015-02-26 09:57:38.0) Response from Bweh at Thorlabs USA: We don't have a maximum acceptable power level but Olympus recommends limiting the power input to <100mW for collimated light and <20mW for focused light. matthias.beck
(posted 2014-05-20 09:35:51.07) Dear Sir/Madam, i would like to ask for further specifications with regard to the microscope objective lense 20X Olympus Plan Achromat Objective, 0.4 NA, 1.2 mm WD.
It is written, that the transmission is in the visible range. What kind of glass is the lense made of and how long is the glass. (I am interested in the dispersion added to a short laser pulse). Further, how far does the transmission range reach with regard to upper and lower end of the visible wavelength range, i.e. is the lense suitable for a wavelength range 500 nm - 1400 nm, or will there be severe cutoff in the IR range.
I would appreciat if you could send me some specs / data.
Regards,
M. Beck besembeson
(posted 2014-05-21 04:41:48.0) A response from Bweh Esembeson at Thorlabs USA. Thanks for contacting us. The RMS20X is manufactured by Olympus and at this time, we have limited information about detail specifications. For example we know that the transmission at 834nm is about 67% but we don't have data about the transmission up to 1400nm or the thickness of the lenses. You may consider contacting Olympus for more detail information. I hope this helps and let me know please if I can further assist you. bill.wilson
(posted 2014-05-11 19:48:32.7) At UWA have many microscopes - Nikon, Leica and Olympus, looking for optics for a variety of purposes. Very painful being treated as new buyer each time you go on line. I know what I want. Open your catalogue for experienced microscopists. We are the people who know what we want and will be spending money. You will not snare a new buyer on-line. My staff would be sacked if they fell for online tricks! besembeson
(posted 2014-05-15 09:21:50.0) Response from Bweh E at Thorlabs: Thanks for contacting Thorlabs.
We have all of our products online and our prices are posted. If there is a system that you are interested in and you would like to receive more information or pricing, please feel free to contact me directly and I can assist you in this.
We recently started a special catalog for Life Science researchers. This is can be found at the following link, including our V21 catalog: http://www.thorlabs.com/support.cfm?section=7&viewTab=4&catalogGroup=LS
Let me know if there are any questions. If you need someone to call you to discuss your interests further, provide me with a phone number and a convenient time to call and I will do that for you. samavial
(posted 2014-03-25 21:18:49.553) Which is (or how could I calculate it) the maximun possible entrance NA for the RMS40X if I use a condenser lens before it (focaliced at the WD)? And, which lens would fix the best for that if my light (colimated) beam has a diameter of about 8mm?
Thanks.
Sara. besembeson
(posted 2014-03-27 04:35:55.0) Response from Bweh E at Thorlabs: Thanks for contacting Thorlabs. The numerical aperture of this objective is 0.65 and the working distance is 0.6mm. So it is best to use a condenser with a matching or smaller numerical aperture to get most signal through the objective. I will send you separate email about your application to discuss the second part of your question. basili
(posted 2014-01-28 06:49:57.283) I would like know the beam spot size from achromatic objective RMS4X, when 3.6mm collimated beam is injected to it a 638nm wavelength. Or which exactly formula that can be applied to calculate beam spot size generated by RMS4X? jlow
(posted 2014-01-28 08:09:15.0) Response from Jeremy at Thorlabs: The RMS4X is diffraction limited at 638nm so you can use the diffraction limited spot size calculation to estimate the focused spot size. Focused spot size = (4*wavelength*focal length)/(pi*input beam diameter). This assumes a well collimated round Gaussian beam. dlaminiphumla.p
(posted 2013-10-11 02:14:43.87) what is the attenuation (power loss in dB) of the RMS4X tcohen
(posted 2013-10-14 11:44:00.0) Response from Tim at Thorlabs: Because it’s a multi-lens system, the losses from the AR coated optics will compound to make the attenuation more wavelength dependent than a single lens with a BBAR coating. A sample transmission plot shows 80% at 400nm, rising to >95% at 500-700nm and back down to 80% at ~850nm. I’ll contact you to discuss your particular wavelengths and provide a sample curve. basili
(posted 2013-06-24 07:11:22.883) Would you please let me know the effective focal length of RMS4X achromatic objective. sharrell
(posted 2013-06-24 10:25:00.0) Response from Sean at Thorlabs: Thank you for using our feedback tool. The effective focal length of the RMS4X objective is 45 mm. This specification and others may be found by clicking on the Specs tab on the page. I’ll look to see how we might make this information more prominent. tcohen
(posted 2012-06-21 15:54:00.0) Response from Tim at Thorlabs: Thank you for your interest in our objectives! We currently do not have operating temperature specs for these objectives. I will contact you to find out which objective you are interested in data for so that we may provide more information. elizabethdoesphysics
(posted 2012-06-19 13:34:42.0) Are there specs stating the operable temperature range for these objectives? We are considering heating a sample and viewing it with an objective. However, the objective may get hot during the process (it takes about 1.5 days at a temperature of about 50 to 60 degrees C). Would these microscope objectives tolerate such use? bdada
(posted 2012-01-23 09:56:00.0) Response from Buki at Thorlabs:
Thank you for using our feedback forum. An objective with 10, 20, 40X, etc and no Focal Length designation will typically have an EFL equal to the "Tube Length" divided by the magnification. Typical tube length is 200mm so for a 10X objective the EFL is 200/10 = 20mm EFL. This is the approximate EFL and NOT the working distance. Working distance for a 10X objective would be somewhere around 15mm.
There are other common tube lengths but the more common ones are 200mm and 160mm. Please contact TechSupport@thorlabs.com if you have any questions. david.szwer
(posted 2012-01-20 13:09:43.0) Dear ThorLabs,
I am considering buying one of the infinity-corrected microscope objectives for use as an output collimator for an optical fibre. The output beam radius is very important, and I can calculate it using the fibre's numerical aperture, and the objective's effective focal length.
However, I can't find details of the effective focal lengths for these objectives. Is there another way to calculate the beam size using the information you give?
Best regards,
David. jjurado
(posted 2011-03-18 10:35:00.0) Response from Javier at Thorlabs to Lehmann: Thank you for contacting us with your request. The entrance aperture for these microscope objectives can be calculated using the following formula:
EA = 2 * EFL * tan [arcsin(NA)].
So, for an objective like the RMS4X, the entrance aperture is 9.1 mm.
I will contact you directly for further support. Lehmann
(posted 2011-03-17 13:05:06.0) I have a question about these microscope objectives. I need to focus a laser to a certain spot size. The given values for the NA is based, I assume, that one fills the input lens. In order to calculate the effective NA for an input TEM00 beam, I must know the input size corresponding to the limiting aperture, but I do not see this listed. Perhaps this the effective focal length times the listed NA. Please pass along information that will allow me to calculate the focal spot size from the wavelength and input beam diameter, assuming a TEM00 beam. Thorlabs
(posted 2010-07-27 17:55:26.0) Response from Javier at Thorlabs to kearly500: Thank you for your feedback. We do not have concise values for the damage threshold of these lenses. However, as a guideline, Olympus recommends limiting the power input to <20mW for focused light and <100mW for collimated light. kearly500
(posted 2010-07-27 11:40:40.0) Hi, Im wondering what the damage threshold is for the RMS40X. Were using it to fiber couple a 2W solid state laser at 532 nm, and I wanted to know if we need to attenuate beforehand. Adam
(posted 2010-04-15 09:32:19.0) A response from Adam at Thorlabs to Albert: While it is possible to use the RMS threaded objectives with the DCC1645C, I think we need more information about your application before we confirm. We would need to know information about your object size and distance. I will email you directly to get this information. On a side note, to connect the RMS threaded objective to the DCC1645C, one would need to use a SM1A3(SM1 to RMS threaded adapater), and a SM1A9(SM1 to C-mount threaded adapter). albert
(posted 2010-04-15 06:14:07.0) Dear Sirs,
We are going to develop a digital microscopic imaging system by using your DCC1645C, MAX203, BSC102 and objective lens(RMS Series). I would like to know if it is possible to install RMS lens to DCC1645C and get the microscopic image.
If the answer is not, how we can integrate such kind of imaging systm by using your existing products.
Look forward to getting your advice ASAP.
Albert Lin
Unique Instruments Co., Ltd.
6F., No.15, Lane 12, Xingzhong Rd., Nangang District, Taipei City 115, Taiwan (R.O.C.)
Web: www.unii.com.tw
email: albert@unii.com.tw
Tel:+886-2-2654-6101
Fax:+886-2-2654-6102 Adam
(posted 2010-03-24 11:35:49.0) A response from Adam at Thorlabs: At this time, Olympus does not provide us with information on the focal shift of these lenses. Since we cannot get this information from Olympus, we cannot provide concrete numbers. The RMS40X is designed more for red and blue wavelengths, so the shift from 650-750nm will be slightly larger than that of a typical objective, 3-4um. The focal shift of the C340TME-B lens is 20um over the range of 650-750nm. I noticed that an email address was not provided. If you have further questions, please feel free to respond to the feedback or send an email to techsupport@thorlabs.com. user
(posted 2010-03-23 11:23:28.0) I am interested in the typical focal shift around 650-750nm. In addition I would like to know the maximum diffraction limited range around 700nm.
I am thinking about this objective or the C340TME-B lens, to collect light from a point like ligth source in the above mentionned wavelength regime.
Thanks klee
(posted 2009-10-19 18:26:23.0) A response from Ken at Thorlabs to plouis: These objectives are primarily designed for blue and red region. However, they still have about 83% transmittance at 800nm so they should work. plouis
(posted 2009-10-19 16:45:10.0) I would like to know if it possible to use these lenses for coupling 830 nm light (photons from SPDC) into SM (and MM) fibers using your fiber launch system. technicalmarketing
(posted 2009-03-22 08:33:38.0) Response to jbao from Inge at Thorlabs: These microscope objectives can be mounted to our lens tubes using an SM1A3 adapter. jbao
(posted 2009-03-21 17:07:00.0) do you have tube lens for these objectives? technicalmarketing
(posted 2008-02-07 09:14:45.0) In response to dutertes inquiry, we have contacted our optics department. Unfortunately, Olympus does not provide us with transmission curves for their objectives. I apologize that we cannot be of more help to you. Perhaps Olympus would be willing to provide that information if you contacted then directly. duterte
(posted 2008-02-05 04:40:14.0) Could you please tell me what are the transmissions for the infinity-corrected microscope objectives UIS2 :
- 4X Microscope Objective, 18.5 mm WD
- 10X Microscope Objective, 10.6 mm WD
- 20X Microscope Objective, 0.4 NA, 1.2 mm WD
- 40X Microscope Objective, 0.65 NA, 0.6 mm WD
At 1064 nm and if it’s possible at 1550 nm.
With best regards,
Charles DUTERTE technicalmarketing
(posted 2007-10-25 15:12:01.0) We are currently in the process of updating this page to inlcude new items. A link to microscopy tools will appear in the family image shortly. acable
(posted 2007-10-25 14:32:36.0) It would be nice to link the Microscopy Tools section to this product page. |
Zoom| Protective Accessories | |
|---|---|
| Objective | Objective Case |
| TL1X-SAP | Lid: OC2M25 Canister: OC24 |
| TL2X-SAP | Lid: OC2M25 Canister: OC22 |
| TL4X-SAP | |
| TL10X-2P | Lid: OC2M32 Canister: OC24 |
Click to Enlarge
The TL1X-SAP objective includes a removable wave plate that is attached via magnets to the end of the objective barrel. White markings on the end of the barrel and a black dot on the wave plate serve as reference points when rotating the wave plate.
- Infinity-Corrected Super Apochromatic Design
- Ideal for Imaging or Focusing Laser Light
- M25 x 0.75 or M32 x 0.75 Threading
- Designed for a Tube Lens Focal Length of 200 mm
- Click Here for Full Presentation
Thorlabs offers super apochromatic microscope objectives with 1X, 2X, 4X, or 10X magnification. The objectives are designed to provide axial color correction over a wide field of view with no vignetting over the entire field. Each objective is designed for use with a tube lens focal length of 200 mm and has optical elements that are AR-coated for improved transmission. For more details on these objectives, please click the info icons (
) below or see the full presentation.
Our 1X telecentric objective is ideal for machine vision applications and features a removable magnetic waveplate that minimizes back reflections when used with an epi-illuminated system, thus enabling an increase in contrast; see the image to the right. Our 2X and 4X objectives have high numerical apertures (NA), making them ideal for widefield imaging. Lastly, our 10X objective is designed for multiphoton imaging applications and provides excellent transmission out to 1300 nm.
All objectives are shipped in an objective case comprised of a lid and container; please see the table to the upper right for compatible replacement cases for each objective. Each objective housing is engraved with the item #, magnification, NA, wavelength range, and working distance. The housings are designed for a tube lens of focal length 200 mm. The TL1X-SAP, TL2X-SAP and TL4X-SAP objectives have M25 x 0.75 external threading, while the TL10X-2P objective has M32 x 0.75 external threading. To use the objectives with a different thread standard, please see our microscope objective thread adapters.
The TL1X-SAP, TL2X-SAP and TL10X-2P objectives have parfocal lengths of 95.0 mm, while the TL4X-SAP objective has a 60.0 mm parfocal length, respectively (see the Specs tab for complete specifications). To use these objectives alongside each other, we offer the PLE351 parfocal length extender to increase the parfocal length of the TL4X-SAP objective from 60.0 mm to 95.0 mm.
| Item # | Wavelength Range | Ma | WD | EFL | NA | EPb | OFN | PFL | Cover Glass Thickness |
Performance Graphs |
AR Coating Reflectance |
Pulsed Damage Threshold |
Objective Threading |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| TL1X-SAP | 420 - 700 nm | 1X | 8.0 mmc | 200 mm | 0.03 | 12 mm | 22 | 95 mmc | 0 - 5.0 mm | |
Ravg < 0.5% (420 - 700 nm) |
- | M25 x 0.75; 3.8 mm Depth |
| TL2X-SAP | 350 - 700 nm | 2X | 56.3 mm | 100 mm | 0.1 | 20 mm | 95 mm | 0 - 5.0 mm | |
Ravg < 0.5% (350 - 700 nm) |
M25 x 0.75; 3.2 mm Depth |
||
| TL4X-SAP | 350 - 700 nm | 4X | 17.0 mm | 50 mm | 0.2 | 60 mm | 0 - 5.0 mm | |
M25 x 0.75; 3.6 mm Depth |
||||
| TL10X-2P | 400 - 1300 nm | 10X | 7.77 mm | 20 mm | 0.5 | 95 mm | 0 - 2.6 mmd | |
Rabs < 2.5% (400 - 450 nm) Rabs < 1.75% (450 - 1300 nm) |
M32 x 0.75; 3.2 mm Depth |
Zoom
- AR Coated for 240 - 360 nm
- Ideal for Laser Focusing and UV Imaging Applications
- Diffraction-Limited Performance
- Designed for a Tube Lens Focal Length of 200 mm
- 10X, 20X, or 50X Magnification
Thorlabs MicroSpot objectives provide long working distances while keeping axial focal shift low. Their optical design is chromatically optimized in the UV wavelength range. Diffraction-limited performance is guaranteed over the entire clear aperture. These objectives are ideal for laser cutting, surgical laser focusing, and spectrometry applications. They can also be used for scanning and micro-imaging applications like brightfield imaging under narrowband, UV laser illumination. Each objective is shipped in an objective case comprised of an OC2M26 lid and an OC24 canister.
Each objective is engraved its class, magnification, numerical aperture, wavelength range, a zero (noting that it is to be used to image a sample without a cover glass) and optical field number. For an explanation of the defining properties of these objectives, please see the Objective Tutorial tab.
Thorlabs can provide these objectives with custom AR coatings on request by contacting Tech Support; options include broadband NUV (325 nm - 500 nm), dual band (266 and 532 nm), and laser line (248 nm, 266 nm, 355 nm, or 532 nm). We also offer additional MicroSpot objectives for laser-focusing applications in the UV as well as visible and near-IR wavelengths.
| Item # | Wavelength Range |
Ma | WD | EFL | NA | EPb | Spot Sizec |
Typical Transmission |
OFN | PFL | Cover Glass Thickness |
AR Coating Reflectanced |
Pulsed Damage Threshold |
Objective Threading |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| LMUL-10X-UVB | 240 - 360 nm | 10X | 20.0 mm | 20 mm | 0.25 | 10.0 mm | 1.4 µm |  Raw Data |
24 | 95.0 mm | 0 mm | (240 - 360 nm) |
5.0 J/cm2 (355 nm, 10 ns, 20 Hz, Ø0.342 mm) |
M26 x 0.706; 5 mm Depth |
| LMUL-20X-UVB | 20X | 15.3 mm | 10 mm | 0.36 | 7.2 mm | 1.0 µm |  Raw Data |
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| LMUL-50X-UVB | 50X | 12.0 mm | 4 mm | 0.42 | 3.4 mm | 0.7 µm |  Raw Data |
Zoom- Long Working Distance
- Infinity-Corrected Plan Apochromat Design
- M26 x 0.706 Threading
- Designed for a Tube Lens Focal Length of 200 mm
- 95 mm Parfocal Length
Thorlabs offers Mitutoyo Plan Apochromat Objectives with 5X, 7.5X, 10X, 20X, 50X, or 100X magnification. They feature a flat field of focus and chromatic correction over their operating ranges: either 436 nm to 656 nm or 480 nm to 1800 nm. The long working distance provides a wide space between the lens surface and the object making them ideal for machine vision applications. Each objective is engraved with its class, magnification, numerical aperture, a zero (noting that it is to be used to image a sample without a cover glass) and the tube lens focal length for which the specified magnification is valid. For an explanation of the defining properties of these objectives, please see the Objective Tutorial tab. If the case shipped with each of these objectives is lost or broken, Thorlabs offers an objective case (item #s OC2M26 and OC24) that can be used as a replacement.
The objectives have external M26 x 0.706 threads; to use these objectives with a different thread standard, please see our microscope objective thread adapters. These objectives do not feature adjustment to correct for cover glass thickness and should be used without a cover slip.
| Item # | Wavelength Range | Ma | WD | EFL | NA | EPb | Spot Sizec |
Typical Transmission | OFN | PFL | Cover Glass Thickness |
AR Coating Reflectance |
Pulsed Damage Threshold |
Objective Threading |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| MY5X-802 | 436 - 656 nm | 5X | 34.0 mm | 40 mm | 0.14 | 11.2 mm | 2.5 µm |  |
24 | 95 mm | 0 mm | Proprietary | - | M26 x 0.706; 5 mm Depth |
| MY7X-807 | 7.5X | 35.0 mm | 26.7 mm | 0.21 | 11.2 mm | 1.7 µm | Proprietary | |||||||
| MY10X-803 | 10X | 34.0 mm | 20 mm | 0.28 | 11.2 mm | 1.3 µm |  |
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| MY20X-804 | 20X | 20.0 mm | 10 mm | 0.42 | 8.4 mm | 0.8 µm |  |
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| MY50X-805 | 50X | 13.0 mm | 4 mm | 0.55 | 4.4 mm | 0.6 µm |  |
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| MY100X-806 | 100X | 6.0 mm | 2 mm | 0.70 | 2.8 mm | 0.5 µm |  |
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| MY5X-822 | 480 - 1800 nm | 5X | 37.5 mm | 40 mm | 0.14 | 11.2 mm | 2.5 µm |  |
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| MY10X-823 | 10X | 30.5 mm | 20 mm | 0.26 | 10.4 mm | 1.3 µm |  |
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| MY20X-824 | 20X | 20.0 mm | 10 mm | 0.40 | 8.0 mm | 0.9 µm |  |
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| MY50X-825 | 50X | 17.0 mm | 4 mm | 0.42 | 3.4 mm | 0.8 µm |  |
Microscope Objectives, Dry