Edmund Optics^®

The unique absorption properties of 2µm lasers allow them to create small and precise cuts for medical and materials processing applications

LC (Low Cost) Fixed YAG Beam Expanders are simple 2-element, cost-effective solutions to beam expansion.

The length of a laser resonator determines the laser’s resonator modes, or the electric field distributions that cause a standing wave in the cavity.

より身近になった紫外 (UV) レーザーが切り開く新たな可能性。従来のUVレーザーは極めて高価で大型だったが、高エネルギーのUV光子により、精度と性能が向上し、新世代の小型・低価格のUVレーザーがますます身近に。半導体検査、顕微鏡、殺菌の進化に貢献。

レーザー誘起損傷閾値 (LIDT) としても知られるレーザー損傷閾値 (LDT) は、光学部品をレーザーアプリケーションに実装する際に考慮すべき最も重要な仕様の一つです。エドモンド・オプティクスは、ARコートが施されたTECHSPEC® レンズ製品の多くに対し、レーザー損傷閾値 (レーザー耐力) か典型エネルギー密度限界のいずれかのスペックを規定しています。

レーザーコンポーネントにおけるレーザー誘起損傷閾値 (LIDT) の理解と規定について。各ビームにおけるレーザー強度、様々な損傷メカニズムについて。

Lasers can be used for a variety of applications. Learn how lasers work, different elements, and the differences between laser types at Edmund Optics.

Follow laser crystals through their entire manufacturing process from fabrication, to coating, to quality control in the Edmund Optics Florida facility.

Understanding the most common laser sources, modes of operation, and gain media provides the context for selecting the proper laser for your specific application.

Compare Coherent Laser specifications with the Edmund Optics selection guide.

Do you need to integrate optical components into a laser system? Make sure you consider laser damage threshold before you do! Find out more at Edmund Optics.

A new generation of compact, cost-effective ultraviolet (UV) lasers is allowing more applications to benefit from the increased precision of UV wavelengths.

Many challenges can arise when aligning a laser beam; knowing specific tips and tricks can help simplify the process. Learn more at Edmund Optics.

Fluorescence imaging systems are composed of three major components, an illumination source, a photo-activated fluorophore sample, and detector.

Monolithic Reflective Beam Expanders are ideal for applications requiring broadband or achromatic beam expansion.

Edmund Optics utilizes Diamond Turning to produce a wide range of high precision optical components.

Beam Conditioning Optics for UV, IR, and Broadband Lasers

Learn how Highly-Dispersive Mirrors compensate for dispersion and compress pulse duration in ultrafast laser systems, which is critical for maximizing performance.

Schwarz Mirrors minimize unwanted stray light using an opaque, engineered fused silica substrate that absorbs light that would otherwise be transmitted.

Edmund Optics' component list and steps provided are used to successfully build an Optical Isolator.

不要な迷光を最小化するSCHWARZ ブラックミラーについて。不要な透過は、ミラーの基板を直接通過したり、基板内でゴースト反射を起こしたりするため、レーザーシステムの性能を低下させ、さらにはレーザーの安全性の問題を引き起こすこともあります。

Beam Shaping for High Power and Short Pulse Durations

Advances in microscopy, imaging, and extreme ultraviolet optics

Specialized coatings can minimize thermal lensing in ultrafast laser systems, which are particularly susceptible to detrimental thermal effects.

Seeing around corners is no longer science fiction thanks to ultrafast lasers and sensitive cameras

Do you have a question about spatial filters? Learn more about how spatial filters are used with lasers and improve a beam at Edmund Optics.

Advances in Smart Materials, Imaging, and Ultrafast Laser Optics

Axicons can be used in a variety of different fields. Find out more about axicons and how to use them in applications at Edmund Optics.

コネクテッドワールドを実現する高速かつ安全なワイヤレス通信、フリースペース光通信とは？レーザーを用いたフリースペース光 (FSO) 通信には、衛星から望遠鏡のような地上の基地局への伝送、衛星から別の衛星への伝送、地上の異なる場所間の伝送等が含まれます。