Name: 25.4mm Dia., 1064nm, λ/4 High Energy Waveplate
SKU: 39-178
Price: NT$27,125

25.4mm Dia., 1064nm, λ/4 High Energy Waveplate

High Energy Quartz Waveplates

Stock #39-178 聯絡我們

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NT$27,125

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NT$27,125

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NT$25,165

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曲線:pdf

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EO Spec Sheet Download All

Specifications

概況

Type:

High Energy Waveplate

物理和機械特性

Clear Aperture CA (mm):

18.0

Diameter (mm):

25.40

Dimensional Tolerance (mm):

+0/-0.2

Construction:

Optically Bonded on UVFS (C7980) Substrate

Parallelism (arcsec):

光學特性

Coating:

R_avg <0.2%

Design Wavelength DWL (nm):

1064

Crystalline Quartz

Retardance:

λ/4

Surface Quality:

20-10

Transmitted Wavefront, P-V:

<λ/10 @ 632.8nm

Retardance Tolerance:

λ/300 @ 20°C

>20 J/cm² @ 1064nm, 10ns, 10Hz

Retardance Order:

1st

螺紋和安裝

Mount Thickness (mm):

6 ±0.2

Regulatory Compliance

RoHS 2015:

Compliant

Certificate of Conformance:

View

Reach 240:

Compliant

產品概覽

損傷閾值高達 20 J/cm² 以上 (在 1064nm 情況下)
具有 λ/4 與 λ/2 的相位差
採用黑色陽極電鍍鋁接口
提供紫外線至近紅外線的設計波長

高能量石英波片是為雷射應用所設計，可在 1064nm 情況下承受高達 20 J/cm² 以上的能量密度。這些波片具備寬廣的作業溫度範圍，適合惡劣環境使用。高能量石英波片針對從紫外線到近紅外線的離散設計波長，提供λ/4 與 λ/2 相位差版本，階數則視設計波長和相位差而定。這些石英波片安裝於黑色陽極電鍍鋁製外殼，輕鬆實現系統整合，並提供寬廣的受光角，盡可能降低調整靈敏度。

Accessories

成像鏡頭選擇器

Frequently Purchased Together

#03-627 - C-Mount Male to Olympus (RMS/DIN) Female Step-Down Adapter

NT$1,654

#03-629 - C-Mount Double Male Thread Ring

NT$1,164

#33-318 - 25.4mm 532nm, High Energy Polarizing Cube Beamsplitter

NT$40,600

#33-319 - 25.4mm 1064nm, High Energy Polarizing Cube Beamsplitter

NT$40,600

資源

Filter

Introduction to Polarization

Is polarization a new topic for you? Learn about key terminology, types, and more information to help you understand polarization at Edmund Optics.

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Laser-Cut Polymer Polarizer and Retarder Quote Tool

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Polymer Polarizers and Retarders

Polymer polarizers and retarders, consisting of sheets of polyvinyl alcohol and TAC cellulose triacetate, alter the polarization of light.

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Polarizer Selection Guide

Edmund Optics' Polarizer Selection Guide refines your search for a specific type of polarizer.

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Understanding Waveplates and Retarders

Waveplates (retarders) are different when used in polarized light than unpolarized light. Consider terminology, fabrication, or applications at Edmund Optics.

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How Do 3D Movies Work? Polarization

Optical Engineer Katie Schwertz explains how 3D movies work because of polarization in a kid-friendly way.

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Polarization Overview - Part 1: Polarization Basics

Polarizers are optical components designed to filter, modify, or analyze the various polarization states of light.

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Polarization Overview - Part 2: Waveplates & Retarders (Advanced)

Waveplates and retarders are optical components designed to transmit light while modifying its polarization state without attenuating, deviating, or displacing the beam.

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You offer many types of polarizers. What are some key benefits to help me decide which is best for my application?

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Are the polarizers shipped with a protective film?

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What is the difference between s- and p-polarization states?

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What are the meanings for the different terms used for polarizers?

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How can I tell what the polarization axis is for a linear polarizer?

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When you list the average transmission of a polarizer, what is the difference between single, parallel, and crossed?

現在查看

I have a linear polarizer glass filter and would like to create circularly polarized light. What type of optics do I need for this?

現在查看

What is the maximum amount of light a polarizer can transmit?

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Does the circular polarizer material have to face a particular direction?

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What is the fast and slow axis of a retarder and how do they differ?

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How can I find the fast and slow axes of a retarder?

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What is the difference between multiple and zero-order retarders and when should I pick one over the other?

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How can I determine if a retarder is quarter or half wave?

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Can I adapt a retarder for use with a specific wavelength other than the design wavelength?

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What is the benefit of polymer retarders?

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Analyzer

現在查看

Birefringence

現在查看

Circular Polarizer

現在查看

Polarization

現在查看

Polarizer

現在查看

Polarizing Efficiency

現在查看

P-Polarization

現在查看

Retardance

現在查看

Retarder (Waveplate)

現在查看

S-Polarization

現在查看

Unpolarized

現在查看

Wire Grid Polarizer

現在查看

Successful Light Polarization Techniques

Are you looking for a solution to common imaging problems? Discover different polarization techniques to improve your image at Edmund Optics.

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Polarization Directed Flat Lenses Product Review

Polarization Directed Flat Lenses, which are formed with polymerized liquid crystal thin-film, create a focal length that is dependent on polarization state.

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Polarizers Review

Polarizers are used in a wide range of imaging and research and development applications.

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Does the polarization of light change after reflecting off a mirror?

現在查看

Do diffusers affect the polarization of light?

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Does the polarization of light change when it passes through a beamsplitter?

現在查看

I would like to split light from a circularly polarized laser source into two beams. What happens when it passes through a cube beamsplitter – both non-polarizing and polarizing?

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Does light entering a multimode fiber undergo a polarization change during propagation through the fiber? If so, can the emerging light be linearly polarized by placing a polarizer at the fiber’s output end?

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Why does the polarization of a laser matter?

The polarization state of a laser source is important for many different applications.

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Extinction Ratio

現在查看

Non-Polarizing Beamsplitter

現在查看

Polarizing Beamsplitter

現在查看

Optical Microscopy Application: Differential Interference Contrast

Differential interference contrast (DIC) is one of the polarization techniques that can be used in optical microscopy. Learn about this technique at Edmund Optics.

現在查看

雷射偏振：偏振在雷射應用的重要性

了解雷射的偏振對於許多應用至關重要，因為偏振會影響反射率、聚焦光束和其他關鍵行為。

現在查看

25.4mm Dia., 1064nm, λ/4 High Energy Waveplate

Specifications

概況

物理和機械特性

光學特性

螺紋和安裝

Regulatory Compliance

產品概覽

Accessories

相關產品

成像鏡頭選擇器

Frequently Purchased Together

資源

Introduction to Polarization

Laser-Cut Polymer Polarizer and Retarder Quote Tool

Polymer Polarizers and Retarders

Polarizer Selection Guide

Understanding Waveplates and Retarders

How Do 3D Movies Work? Polarization

Polarization Overview - Part 1: Polarization Basics

Polarization Overview - Part 2: Waveplates & Retarders (Advanced)

You offer many types of polarizers. What are some key benefits to help me decide which is best for my application?

Are the polarizers shipped with a protective film?

What is the difference between s- and p-polarization states?

What are the meanings for the different terms used for polarizers?

How can I tell what the polarization axis is for a linear polarizer?

When you list the average transmission of a polarizer, what is the difference between single, parallel, and crossed?

I have a linear polarizer glass filter and would like to create circularly polarized light. What type of optics do I need for this?

What is the maximum amount of light a polarizer can transmit?

Does the circular polarizer material have to face a particular direction?

What is the fast and slow axis of a retarder and how do they differ?

How can I find the fast and slow axes of a retarder?

What is the difference between multiple and zero-order retarders and when should I pick one over the other?

How can I determine if a retarder is quarter or half wave?

Can I adapt a retarder for use with a specific wavelength other than the design wavelength?

What is the benefit of polymer retarders?

Analyzer

Birefringence

Circular Polarizer

Polarization

Polarizer

Polarizing Efficiency

P-Polarization

Retardance

Retarder (Waveplate)

S-Polarization

Unpolarized

Wire Grid Polarizer

Successful Light Polarization Techniques

Polarization Directed Flat Lenses Product Review

Polarizers Review

Does the polarization of light change after reflecting off a mirror?

Do diffusers affect the polarization of light?

Does the polarization of light change when it passes through a beamsplitter?

I would like to split light from a circularly polarized laser source into two beams. What happens when it passes through a cube beamsplitter – both non-polarizing and polarizing?

Does light entering a multimode fiber undergo a polarization change during propagation through the fiber? If so, can the emerging light be linearly polarized by placing a polarizer at the fiber’s output end?

Why does the polarization of a laser matter?

Extinction Ratio

Non-Polarizing Beamsplitter

Polarizing Beamsplitter

Optical Microscopy Application: Differential Interference Contrast

雷射偏振：偏振在雷射應用的重要性