Precision Pinhole Kits
- Ten Stainless Steel Precision Pinholes in Each Kit
- Pinhole Sizes from Ø5 μm to Ø9 mm
- Mounted in Ø1/2" or Ø1" Aluminum Housings
PKIT1K
Ø5 µm - Ø100 µm Pinholes, Ø1/2" Housings
PKIT4K
Ø2 mm - Ø9 mm Pinholes,
Ø1" Housings
P10HK
Ø10 µm Pinhole,
Ø1/2" Housing
P4000K
Ø4 mm Pinhole,
Ø1" Housing
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Apertures Selection Guide |
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Single Precision Pinholes |
Circular in Stainless Steel Foils |
Circular in Stainless Steel Foils, Vacuum Compatible |
Circular in Gold-Plated Copper Foils |
Circular in Tungsten Foils |
Circular in Molybdenum Foils |
Square in Stainless Steel Foils |
Pinhole Kits |
Pinhole Wheels |
Manual |
Motorized |
Pinhole Spatial Filter |
Slits |
Annular Apertures |
Half-Aperture Foils for Knife-Edge Scans |
Alignment Tools |
Click for Details
Dimensions for Mounted Stainless Steel Pinholes in Ø1" Housing
Click to Enlarge
Dimensions for Mounted Stainless Steel Pinholes in Ø1/2" Housing
Features
- Ten Stainless Steel Precision Pinholes in Each Kit Covering Four Diameter Ranges:
- PKIT1HK and PKIT1K: Ø5 µm - Ø100 µm
- PKIT2HK and PKIT2K: Ø30 µm - Ø500 µm
- PKIT3HK and PKIT3K: Ø150 µm - Ø1 mm
- PKIT4K: Ø2 mm - Ø9 mm
- Stainless Steel Foils are Blackened on Both Sides for Increased Absorbance
- Ø1/2" or Ø1" Black-Anodized Aluminum Housings Engraved with Item #
- Kits are Packaged in Protective Plastic Cases for Easy Storage
The mounted precision pinholes in the kits below are available with pinhole sizes from Ø5 µm to Ø1 mm (Ø1/2" housings) or Ø5 µm to Ø9 mm (Ø1" housings). They are fabricated from stainless steel foils that are blackened on both sides; see the Graph tab for reflectance information. The foils are mounted in Ø1/2" or Ø1", 0.10" (2.5 mm) thick aluminum housings that are black anodized. Each housing is engraved with the pinhole Item # and the size of the pinhole. If needed, the foils can be taken out of their housings by removing the retaining ring using small tweezers or pliers; use care as the foil is very thin (50 µm).
We also offer pinholes with a variety of other foil materials; see the table to the right for options. More details on our aperture offerings can be found in the Apertures Selection Guide tab.
For many applications, such as holography, spatial intensity variations in the laser beam are unacceptable. Using precision pinholes in conjunction with positioning and focusing equipment such as our KT311(/M) Spatial Filter System creates a "noise" filter, effectively stripping variations in intensity out of a Gaussian beam. Please see the Tutorial tab for more information on spatial filters.
Precision Pinhole Options
Thorlabs' precision pinholes are available with an assortment of fabrication materials and coatings. The choice of a particular size and material should depend on the application. Low-power applications may benefit more from the absorbance of our blackened stainless steel foils, which are offered in anodized-aluminum housings, or our stainless steel foils with a black PVD coating, which are offered in vacuum-compatible stainless steel housings. High-power applications may need the high damage threshold and reflectance of gold-plated copper foils, the high melting point and lower reflectance of our tungsten foils, or the high melting point of our molybdenum foils paired with the low reflectance (4% @ 800 nm) of their black-coated front side. Please see the Foil Comparison and Graph tabs for more information.
Reflectance Graph
Below is a reflectance graph for the blackened stainless steel foils used in the circular precision pinholes. The raw reflectance data can be found here.
Precision Pinhole and Optical Slit Selection Guide | |||||
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Material | Product | ||||
Blackened Stainless Steel | Circular Precision Pinholes | ||||
Square Precision Pinholes | |||||
Optical Slits | |||||
Tungsten Foil | Circular Precision Pinholes | ||||
Stainless Steel with PVD Black Coating |
Circular Precision Pinholes | ||||
Molybdenum Foil (Rear) and Absorptive Polymer Coating (Front) |
Circular Precision Pinholes | ||||
Gold-Plated Copper Foil (Rear) and PVD Black Coating (Front) |
Circular Precision Pinholes | ||||
Gold-Plated Copper Foil (Front) and PVD Black Coating (Rear) |
High-Power Circular Precision Pinholes |
Precision Pinholes and Slits
Thorlabs offers precision pinholes with blackened stainless steel, gold-plated copper, tungsten, or molybdenum foils. Our pinholes with stainless steel foils are blackened on both sides for increased absorbance and are available from stock in circles from Ø1 µm to Ø9 mm and squares from 100 µm x 100 µm to 1 mm x 1 mm. Our stainless steel pinholes with a black PVD coating are vacuum compatible and available in 5 μm to 2 mm diameters. Our pinholes with gold-plated copper foils, plated with gold on one side and black PVD coated on the reverse, are available with pinhole diameters from 5 µm to 2 mm. High-power gold-plated copper foil pinholes are also available, with the gold-plated copper foil on the front face, and a PVD black coating on the rear. Our pinholes with tungsten foils are uncoated and available with pinhole diameters from 5 µm to 2 mm. Lastly, our pinholes with molybdenum foils have an absorptive polymer coating on the front sides and are available with pinhole diameters from 5 µm to 2 mm. We also offer slits in blackened stainless steel foils from stock with slit widths from 5 to 200 µm.
If you do not see what you need among our stock pinhole and slit offerings, it is also possible to special order pinholes and slits that are made with different foil materials, have different hole sizes and shapes, incorporate multiple holes in one foil, or provide different hole configurations. Please contact Tech Support to discuss your specific needs. For more information on the properties of the bulk materials from which the pinholes are fabricated, see the table below.
Material Properties
Depending on the application, it can be important to consider the material properties of the pinhole or slit. The material used to construct the aperture can have varying levels of melting point, density, and thermal conductivity, as detailed in the table below.
Material Properties | ||||
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Material | 300 Series Stainless Steela | Copperb | Tungsten | Molybdenumc |
Melting Point | 1390 - 1450 °C | 1085 °C | 3422 °C | 2623 °C |
Density | 8.03 g/cm3 | 8.96 g/cm3 | 19.25 g/cm3 | 10.28 g/cm3 |
Brinell Hardness | 170 MPa | 878 MPa | 2570 MPa | 1500 MPa |
Damage Thresholdd (10 ns Pulse, 1 kHz @ 355 nm) | 1.54 MW/mm2 | 4.82 MW/mm2 | 9.39 MW/mm2 | 6.34 MW/mm2 |
Thermal Expansion Coefficient | 16.2 (µm/m)/°C | 16.7 (µm/m)/°C | 4.5 (µm/m)/°C | 5.0 (µm/m)/°C |
Specific Heat @ 20 °C | 485 J/(K*kg) | 385 J/(K*kg) | 134 J/(K*kg) | 250 J/(K*kg) |
Thermal Conductivity | 16.2 W/(m*K) | 401 W/(m*K) | 173 W/(m*K) | 138 W/(m*K) |
Thermal Diffusivity @ 300 K | 3.1 mm2/s | 111 mm2/s | 80 mm2/s | 54.3 mm2/s |
Reflectance
The reflectance of the foil material or coating affects performance in a variety of applications. Below is presented a reflectance graph for all the materials and coatings that are offered with our circular and square precision pinholes, as well as our mounted optical slits. The raw reflectance data can be found here.
It is important to note that the front of the gold-plated copper foil circular precision pinholes have a low-reflectance PVD black coating. The rear of these pinholes leaves the gold-plated copper foil bare. This also occurs on the molybdenum foil circular precision pinholes, which have a low-reflectance absorptive polymer coating on the front and the molybdenum foil is left bare on the back.
Principles of Spatial Filters
For many applications, such as holography, spatial intensity variations in the laser beam are unacceptable. Our KT311 spatial filter system is ideal for producing a clean Gaussian beam.
Figure 1: Spatial Filter System
The input Gaussian beam has spatially varying intensity "noise". When a beam is focused by an aspheric lens, the input beam is transformed into a central Gaussian spot (on the optical axis) and side fringes, which represent the unwanted "noise" (see Figure 2 below). The radial position of the side fringes is proportional to the spatial frequency of the "noise".
Figure 2
By centering a pinhole on a central Gaussian spot, the "clean" portion of the beam can pass while the "noise" fringes are blocked (see Figure 3 below).
Figure 3
The diffraction-limited spot size at the 99% contour is given by:
where λ = wavelength, ƒ=focal length and r = input beam radius at the 1/e2 point.
Choosing the Correct Optics and Pinhole for Your Spatial Filter System
The correct optics and pinhole for your application depend on the input wavelength, source beam diameter, and desired exit beam diameter.
For example, suppose that you are using a 650 nm diode laser source that has a diameter (1/e2) of 1.2 mm and want your beam exiting the spatial filter system to be about 4.4 mm in diameter. Based on these parameters, the C560TME-B mounted aspheric lens would be an appropriate choice for the input side of spatial filter system because it is designed for use at 650 nm, and its clear aperture measures 5.1 mm, which is large enough to accommodate the entire diameter of the laser source.
The equation for diffraction limited spot size at the 99% contour is given above, and for this example, λ = (650 x 10-9 m), f = 13.86 mm for the C560TM-B, and r = 0.6 mm. Substitution yields
Diffraction-Limited Spot Size (650 nm source, Ø1.2 mm beam)
The pinhole should be chosen so that it is approximately 30% larger than D. If the pinhole is too small, the beam will be clipped, but if it is too large, more than the TEM00 mode will get through the pinhole. Therefore, for this example, the pinhole should ideally be 19.5 microns. Hence, we would recommend the mounted pinhole P20D, which has a pinhole size of 20 μm. Parameters that can be changed to alter the beam waist diameter, and thus the pinhole size required, include changing the input beam diameter and focal length of focusing lens. Decreasing the input beam diameter will increase the beam waist diameter. Using a longer focal length focusing lens will also increase the beam waist diameter.
Finally, we need to choose the optic on the output side of the spatial filter so that the collimated beam's diameter is the desired 4.4 mm. To determine the correct focal length for the lens, consider the following diagram in Figure 4, which is not drawn to scale. From the triangle on the left-hand side, the angle is determined to be approximately 2.48o. Using this same angle for the triangle on the right-hand side, the focal length for the plano-convex lens should be approximately 50 mm.
Figure 4: Beam Expansion Example
For this focal length, we recommend the LA1131-B plano-convex lens [with f = 50 mm at the design wavelength (λ = 633 nm), this is still a good approximation for f at the source wavelength (λ = 650 nm)].
Note: The beam expansion equals the focal length of the output side divided by the focal length of the input side.
For optimal performance, a large-diameter aspheric lens can be used in place of a plano-convex lens if the necessary focal length on the output side is 20 mm (see AL2520-A, AL2520-B, AL2520-C). These lenses are 25 mm in diameter and can be held in place using the supplied SM1RR Retaining Ring.
Click to Enlarge
Figure 1: The beam circularization systems were placed in the area of the experimental setup highlighted by the yellow rectangle.
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Figure 4: Spatial Filter System
Click to Enlarge
Figure 3: Anamorphic Prism Pair System
Click to Enlarge
Figure 2: Cylindrical Lens Pair System
Comparison of Circularization Techniques for Elliptical Beams
Edge-emitting laser diodes emit elliptical beams as a consequence of the rectangular cross sections of their emission apertures. The component of the beam corresponding to the narrower dimension of the aperture has a greater divergence angle than the orthogonal beam component. As one component diverges more rapidly than the other, the beam shape is elliptical rather than circular.
Elliptical beam shapes can be undesirable, as the spot size of the focused beam is larger than if the beam were circular, and as larger spot sizes have lower irradiances (power per area). Techniques for circularizing an elliptical beam include those based on a pair of cylindrical lenses, an anamorphic prism pair, or a spatial filter. This work investigated all three approaches. The characteristics of the circularized beams were evaluated by performing M2 measurements, wavefront measurements, and measuring the transmitted power.
While it was demonstrated that each circularization technique improves the circularity of the elliptical input beam, each technique was shown to provide a different balance of circularization, beam quality, and transmitted power. The results of this work, which are documented in this Lab Fact, indicate that an application's specific requirements will determine which is the best circularization technique to choose.
Experimental Design and Setup
The experimental setup is shown in Figure 1. The elliptically-shaped, collimated beam of a temperature-stabilized 670 nm laser diode was input to each of our circularization systems shown in Figures 2 through 4. Collimation results in a low-divergence beam, but it does not affect the beam shape. Each system was based on one of the following:
- LJ1874L2-A and LJ1638L1-A Plano-Convex Convex Cylindrical Lenses (Figure 2)
- PS873-A Unmounted Anamorphic Prism Pair (Figure 3)
- Previous Generation KT310 Spatial Filter System with P5S Ø5 µm Pinhole (Figure 4)
The beam circularization systems, shown to the right, were placed, one at a time, in the vacant spot in the setup highlighted by the yellow rectangle. With this arrangement, it was possible to use the same experimental conditions when evaluating each circularization technique, which allowed the performance of each to be directly compared with the others. This experimental constraint required the use of fixturing that was not optimally compact, as well as the use of an unmounted anamorphic prism pair, instead of a more convenient mounted and pre-aligned anamorphic prism pair.
The characteristics of the beams output by the different circularization systems were evaluated by making measurements using a power meter, a wavefront sensor, and an M2 system. In the image of the experimental setup, all of these systems are shown on the right side of the table for illustrative purposes; they were used one at a time. The power meter was used to determine how much the beam circularization system attenuated the intensity of the input laser beam. The wavefront sensor provided a way to measure the aberrations of the output beam. The M2 system measurement describes the resemblance of the output beam to a Gaussian beam. Ideally, the circularization systems would not attenuate or aberrate the laser beam, and they would output a perfectly Gaussian beam.
Edge-emitting laser diodes also emit astigmatic beams, and it can be desirable to force the displaced focal points of the orthogonal beam components to overlap. Of the three circularization techniques investigated in this work, only the cylindrical lens pair can also compensate for astigmatism. The displacement between the focal spots of the orthogonal beam components were measured for each circularization technique. In the case of the cylindrical lens pair, their configuration was tuned to minimize the astigmatism in the laser beam. The astigmatism was reported as a normalized quantity.
Experimental Results
The experimental results are summarized in the following table, in which the green cells identify the best result in each category. Each circularization approach has its benefits. The best circularization technique for an application is determined by the system’s requirements for beam quality, transmitted optical power, and setup constraints.
Spatial filtering significantly improved the circularity and quality of the beam, but the beam had low transmitted power. The cylindrical lens pair provided a well-circularized beam and balanced circularization and beam quality with transmitted power. In addition, the cylindrical lens pair compensated for much of the beam's astigmatism. The circularity of the beam provided by the anamorphic prism pair compared well to that of the cylindrical lens pair. The beam output from the prisms had better M2 values and less wavefront error than the cylindrical lenses, but the transmitted power was lower.
Method | Beam Intensity Profile | Circularitya | M2 Values | RMS Wavefront | Transmitted Power | Normalized Astigmatismb |
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Collimated Source Output (No Circularization Technique) |
Click to Enlarge Scale in Microns |
0.36 | Y Axis: 1.63 |
0.17 | Not Applicable | 0.67 |
Cylindrical Lens Pair | Click to Enlarge Scale in Microns |
0.84 | X Axis: 1.90 Y Axis: 1.93 |
0.30 | 91% | 0.06 |
Anamorphic Prism Pair |
Click to Enlarge Scale in Microns |
0.82 | X Axis: 1.60 Y Axis: 1.46 |
0.16 | 80% | 1.25 |
Spatial Filter | Click to Enlarge Scale in Microns |
0.93 | X Axis: 1.05 Y Axis: 1.10 |
0.10 | 34% | 0.36 |
Components used in each circularization system were chosen to allow the same experimental setup be used for all experiments. This had the desired effect of allowing the results of all circularization techniques to be directly compared; however, optimizing the setup for a circularization technique could have improved its performance. The mounts used for the collimating lens and the anamorphic prism pair enabled easy manipulation and integration into this experimental system. It is possible that using smaller mounts would improve results by allowing the members of each pair to be more precisely positioned with respect to one another. In addition, using made-to-order cylindrical lenses with customized focal lengths may have improved the results of the cylindrical lens pair circularization system. All results may have been affected by the use of the beam profiler software algorithm to determine the beam radii used in the circularity calculation.
Additional Information
Some information describing selection and configuration procedures for several components used in this experimental work can be accessed by clicking the following hyperlinks:
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Apertures Selection Guide | |||
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Aperture Type | Representative Image (Click to Enlarge) |
Description | Aperture Sizes Available from Stocka |
Single Precision Pinholesa |
Circular Pinholes in Stainless Steel Foils | Ø1 µm to Ø9 mm | |
Circular Pinholes in Stainless Steel Foils, Vacuum Compatible |
Ø5 µm to Ø2 mm | ||
Circular Pinholes in Gold-Plated Copper Foils | Ø5 µm to Ø2 mm | ||
Circular Pinholes in Gold-Plated Copper Foils with High-Power Housings |
Ø5 µm to Ø500 µm | ||
Circular Pinholes in Tungsten Foils | Ø5 µm to Ø2 mm | ||
Circular Pinholes in Molybdenum Foils | Ø5 µm to Ø2 mm | ||
Square Pinholes in Stainless Steel Foils | 100 to 1000 µm Square | ||
Slitsa | Slits in Stainless Steel Foils | 3 mm Slit Lengths: 5 to 500 µm Widths 10 mm Slit Lengths: 20 to 500 µm Widths |
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Double Slits in Stainless Steel Foils | 3 mm Slit Lengths with 40, 50, or 100 µm Widths, Spacing of 3X or 6X the Slit Width |
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Half-Apertures | Mounted, Half-Aperture Foils | Half-Apertures for Knife-Edge Scan Measurements | |
Annular Apertures | Annular Aperture Obstruction Targets on Quartz Substrates with Chrome Masks |
Ø1 mm Apertures with ε Ratiosb from 0.05 to 0.85 Ø2 mm Aperture with ε Ratiob of 0.85 |
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Pinhole Wheels | Manual, Mounted, Chrome-Plated Fused Silica Disks with Lithographically Etched Pinholes |
Each Disk has 16 Pinholes from Ø25 µm to Ø2 mm and Four Annular Apertures (Ø100 µm Hole, 50 µm Obstruction) |
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Motorized Pinhole Wheels with Chrome-Plated Glass Disks with Lithographically Etched Pinholes |
Each Disk has 16 Pinholes from Ø25 µm to Ø2 mm and Four Annular Apertures (Ø100 µm Hole, 50 µm Obstruction) |
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Pinhole Kits | Stainless Steel Precision Pinhole Kits | Kits of Ten Circular Pinholes in Stainless Steel Foils Covering Ø5 µm to Ø9 mm |
Kit Item # | Pinhole Diameter (Item #) of Included Parts | |||||||||
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PKIT1HK | Ø5 µm (P5HK) |
Ø10 µm (P10HK) |
Ø15 µm (P15HK) |
Ø20 µm (P20HK) |
Ø25 µm (P25HK) |
Ø30 µm (P30HK) |
Ø40 µm (P40HK) |
Ø50 µm (P50HK) |
Ø75 µm (P75HK) |
Ø100 µm (P100HK) |
PKIT2HK | Ø30 µm (P30HK) |
Ø40 µm (P40HK) |
Ø50 µm (P50HK) |
Ø75 µm (P75HK) |
Ø100 µm (P100HK) |
Ø150 µm (P150HK) |
Ø200 µm (P200HK) |
Ø300 µm (P300HK) |
Ø400 µm (P400HK) |
Ø500 µm (P500HK) |
PKIT3HK | Ø150 µm (P150HK) |
Ø200 µm (P200HK) |
Ø300 µm (P300HK) |
Ø400 µm (P400HK) |
Ø500 µm (P500HK) |
Ø600 µm (P600HK) |
Ø700 µm (P700HK) |
Ø800 µm (P800HK) |
Ø900 µm (P900HK) |
Ø1 mm (P1000HK) |
Kit Item # | Pinhole Diameter (Item #) of Included Parts | |||||||||
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PKIT1K | Ø5 µm (P5K) |
Ø10 µm (P10K) |
Ø15 µm (P15K) |
Ø20 µm (P20K) |
Ø25 µm (P25K) |
Ø30 µm (P30K) |
Ø40 µm (P40K) |
Ø50 µm (P50K) |
Ø75 µm (P75K) |
Ø100 µm (P100K) |
PKIT2K | Ø30 µm (P30K) |
Ø40 µm (P40K) |
Ø50 µm (P50K) |
Ø75 µm (P75K) |
Ø100 µm (P100K) |
Ø150 µm (P150K) |
Ø200 µm (P200K) |
Ø300 µm (P300K) |
Ø400 µm (P400K) |
Ø500 µm (P500K) |
PKIT3K | Ø150 µm (P150K) |
Ø200 µm (P200K) |
Ø300 µm (P300K) |
Ø400 µm (P400K) |
Ø500 µm (P500K) |
Ø600 µm (P600K) |
Ø700 µm (P700K) |
Ø800 µm (P800K) |
Ø900 µm (P900K) |
Ø1 mm (P1000K) |
PKIT4K | Ø2 mm (P2000K) |
Ø2.5 mm (P2500K) |
Ø3 mm (P3000K) |
Ø3.5 mm (P3500K) |
Ø4 mm (P4000K) |
Ø4.5 mm (P4500K) |
Ø5 mm (P5000K) |
Ø7 mm (P7000K) |
Ø7.5 mm (P7500K) |
Ø9 mm (P9000K) |