Annular Aperture Obstruction Targets

Obstruction Diameters Ranging from 50 µm to 1700 µm
1000 µm or 2000 µm Pinhole Diameter
Blocking Region with Optical Density ≥ 6
0.5 mm Thick Quartz Substrate in Ø1" Aluminum Housing

R1DF100

Annular Aperture Target
Obstruction Diameter = 100 µm
Pinhole Diameter = 1000 µm

R1CA1000

Annular Aperture Target
Obstruction Diameter = 850 µm
Pinhole Diameter = 1000 µm

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Overview
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Apertures Selection Guide

Apertures Selection Guide
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

Features

Increase Contrast when Imaging Biological Systems
Filter Out Lower Order Spatial Modes
0.5 mm Thick Quartz Substrate
Blocking Region (OD ≥ 6) Created Using a Low-Reflectivity Chrome Mask
Low-Reflectivity Chrome Mask to Minimize Back Reflections
Aluminum Housing with a 1" Outer Diameter

Thorlabs' Annular Aperture Obstruction Targets (AAOTs) are ideal for increasing the contrast when imaging biological systems or filtering out lower order modes. Each AAOT is characterized by the ratio (ε) between the obstruction diameter (OD) and the pinhole diameter (PD). Thorlabs offers Annular Aperture targets with values of ε between 0.05 and 0.85, with a 1 mm pinhole diameter. These apertures are ideal for high-pass spatial filtering applications. For an ε ratio of 0.85, which is ideal for increasing the lateral resolution of confocal imaging systems, we also offer an aperture with a 2 mm pinhole diameter.

These targets are fabricated from 0.5 mm thick quartz glass substrate that has high transmission in the 400 - 2200 nm wavelength range. The clear aperture annulus is created using a low-reflectivity chrome mask with an optical density ≥ 6 that blocks light from being transmitted though the inner obstruction target and outer obstruction region. The AAOT is then mounted within a housing that has a 1" outer diameter, which allows for mounting within our translation mounts for Ø1" optics. The glass substrate is mounted with the low-reflectivity chrome mask facing towards the engraved side of the housing. To minimize back reflections, we recommend having the low-reflectivity chrome mask facing the light source when used.

Posted Comments:

user (posted 2023-09-12 11:02:43.22)

Could you make customized annular aperture obstruction targets for us?

tberg (posted 2023-10-02 03:40:27.0)

Hello! Thanks for contacting Thorlabs! I have reached out to you to discuss custom options.

Lee Weller (posted 2021-05-21 16:32:46.417)

I'm looking for annular aperture obstruction targets in a 1/2" housing please. Could I make a custom size annular aperture also? 5.5mm PD and ~1.7mm OD

YLohia (posted 2021-05-24 10:37:49.0)

Hello, thank you for contacting Thorlabs. Unfortunately, we cannot offer any customizations on this product line since these products are no longer in production and are pending obsoletion once the stock runs out.

user (posted 2019-11-12 01:28:54.313)

Hello. Can I purchase blank disks? I want to purchase disks without an annular structure at the center. Best regards, Sang.

YLohia (posted 2019-11-12 12:24:45.0)

Hello Sang, thank you for contacting Thorlabs. Custom items can be requested by emailing techsupport@thorlabs.com. We will reach out to you directly to discuss the possibility of offering this.

h.wu (posted 2017-11-29 14:35:26.623)

Could you make customized annular aperture obstruction targets for us?

tfrisch (posted 2017-12-12 04:32:36.0)

Hello, thank you for contacting Thorlabs. We are able to offer a new size of Annular Obstruction Target. This would require a new master to be made and can be cost prohibitive for low quantities. I will reach out to you directly to discuss a formal quote.

kwjae92 (posted 2017-11-06 01:42:06.177)

Hi, my name is woojae Kang and i have a question about annular aperture. Could I make a custom size annular aperture ? I want ~10mm PD and ~8-9mm OD. Thanks.

tfrisch (posted 2017-12-19 04:54:32.0)

Hello, thank you for contacting Thorlabs. A custom size would require a new master which can be cost prohibitive for low quantities. I will reach out to you directly to discuss a formal quote.

aphillips (posted 2017-07-27 15:22:53.21)

I'm looking for annular aperture obstruction targets in a 1/2" housing. What are our options? Can the targets be easily removed from the 1" housing and placed in a custom housing?

tfrisch (posted 2017-08-16 10:03:41.0)

Hello, thank you for contacting Thorlabs. We can provide unmounted versions as a custom. We will reach out to you with a quote.

dan.reynolds (posted 2017-01-06 08:40:40.773)

I'm looking for a high pass filter for a Fourier optics set and one of these annular apertures would fit the bill nicely. However, I might have higher spatial frequencies that are more than 2mm from the center. Could you make one of these with a 15mm pinhole diameter and somewhere between 100 to 3000um obstruction diameter?

tfrisch (posted 2017-01-06 11:12:46.0)

Hello, thank you for contacting Thorlabs. I will reach out to you directly about the specific requirements for your application.

user (posted 2016-04-15 11:23:55.733)

http://www.thorlabs.co.jp/images/tabimages/Annular_Aperture_Target_Equation_D1-182.gif e should be (Pinhole)/(Obstruction)

besembeson (posted 2016-04-15 04:38:05.0)

Response from Bweh at Thorlabs USA: We define this in this case to be the inverse. Please contact me at techsupport@thorlabs.com if you have any questions or need some clarifications.

Apertures Selection Guide
Aperture Type	Representative Image (Click to Enlarge)	Description	Aperture Sizes Available from Stock^a
Single Precision Pinholes^a		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
Slits^a		Slits in Stainless Steel Foils	3 mm Slit Lengths: 5 to 500 µm Widths 10 mm Slit Lengths: 20 to 500 µm Widths
Slits^a		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
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 Ratios^b from 0.05 to 0.85 Ø2 mm Aperture with ε Ratio^b of 0.85
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)
Pinhole Wheels		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)
Pinhole Kits		Stainless Steel Precision Pinhole Kits	Kits of Ten Circular Pinholes in Stainless Steel Foils Covering Ø5 µm to Ø9 mm

Precision pinholes and slits can be special ordered with different aperture sizes, foil materials, shapes, and hole distributions than those offered from stock. Please contact Tech Support with inquiries.
Ratio of the Obstruction Diameter to the Pinhole Diameter

Obstruction Targets: Annular Aperture, 0.05 to 0.50 Ratio

Zoom

Click to Enlarge
Close-Up Photo of an Obstruction Pinhole
OD: Obstruction Diameter
PD: Pinhole Diameter

Pinhole Diameter of 1 mm
Obstruction Diameters of 50 µm, 100 µm, or 500 µm
Ø1" Housing can be Mounted in Many of our Translation Mounts for Fine Alignment
Ideal for High-Pass Spatial Filtering Applications
Can be Used in Our Pre-Assembled Spatial Filter System

These Annular Aperture Obstruction Targets have an obstruction-to-pinhole ratio (ε) of 0.05, 0.10, or 0.50, making them ideal for use as high-pass or edge-enhancement filters. When the Fourier plane is imaged onto the filter, the center region, which contains Gaussian light (TEM₀₀), will become blocked by the center obstruction. This allows the higher order modes of the Fourier plane, which contain diffraction information, to pass through and form the image. This will cause an overall loss of light intensity and generalized, smooth features, but it will enhance any sharp lines or boundaries.

Shown to the right is a close up photo of an obstruction pinhole with the pinhole diameter (PD) and obstruction diameter (OD) labeled. The low-reflectivity chrome-masked area appears black, and light is transmitted through the clear aperture.

Item #	ε Ratio^a	Obstruction Diameter	Pinhole Diameter	Annular Aperture Concentricity		Glass Thickness
Item #	ε Ratio^a	Obstruction Diameter	Pinhole Diameter	with Respect to Housing^b	with Respect to Substrate^c	Glass Thickness
R1DF50	0.05	50 µm	1 mm	<0.41 mm	≤216 µm	0.5 mm
R1DF100	0.10	100 µm
R1DF500	0.50	500 µm

Ratio of the Obstruction Diameter to the Pinhole Diameter (See Photo to the Above Right)
Concentricity of the Annulus with Respect to the Outer Diameter of the Quartz Glass Substrate
Concentricity of the Annulus with Respect to the Outer Diameter of the Aluminum Housing

Obstruction Targets: Annular Aperture, 0.85 Ratio

Zoom

Click to Enlarge
Close-Up Photo of an Obstruction Pinhole
OD: Obstruction Diameter
PD: Pinhole Diameter

ε Ratio of 0.85
Ø1" Housing can be Mounted in Many of our Translation Mounts for Fine Alignment
Ideal for Confocal Microscopy Applications
Can be Used in Our Pre-Assembled Spatial Filter System

These Annular Aperture Obstruction Targets have an obstruction-to-pinhole ratio (ε) of 0.85, making them ideal for increasing the lateral spatial resolution within confocal imaging systems. These filters are designed to be placed directly in front of the output of a light source such as a fiber-coupled laser. The system should be aligned so that the first bright diffraction spot of the light source is larger than the pinhole diameter of the annular aperture.

These annular apertures are often used in confocal and two-photon excitation microscopy to increase the lateral resolution of the imaging system or in confocal theta fluorescence microscopy to increase the lateral and axial resolution of the imaging system.

Item #	ε Ratio^a	Obstruction Diameter	Pinhole Diameter	Concentricity		Glass Thickness
Item #	ε Ratio^a	Obstruction Diameter	Pinhole Diameter	with Respect to Housing^b	with Respect to Substrate^c	Glass Thickness
R1CA1000	0.85	850 µm	1000 µm	<0.41 mm	≤216 µm	0.5 mm
R1CA2000	0.85	1700 µm	2000 µm	<0.41 mm	≤216 µm	0.5 mm

Ratio of the Obstruction Diameter to the Pinhole Diameter (See Photo to the Above Right)
Concentricity of the Annulus with Respect to the Outer Diameter of the Quartz Glass Substrate
Concentricity of the Annulus with Respect to the Outer Diameter of the Aluminum Housing