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Photonics Crystal Library

Your Comprehensive Guide to Photonic Crystals

Welcome to Photonics on Crystals’ (POC) Photonics Crystal Library, a comprehensive resource designed to help you explore and find the perfect photonic crystal solution for your project or application.

Overview of Photonic crystals

Photonic crystals are the foundation of numerous modern technologies, ranging from optical communication to advanced medical imaging and laser systems. They are engineered materials with periodic structures that influence the propagation of light, enabling groundbreaking advancements in controlling and manipulating light for various applications.

The Photonics Crystal Library serves as a complete guide, offering detailed descriptions, properties, and application insights for a wide variety of photonic crystals. Whether you are designing a cutting-edge laser system, creating an optical sensor, or researching next-generation technologies, this page provides a centralized hub to explore various photonic crystal materials and their unique functionalities.

With an organized catalog of crystal types, the library is designed to simplify your search and provide technical information at your fingertips. You will find essential details about non-linear crystals, laser crystals, infrared crystals, and more, allowing you to make informed decisions based on your project requirements.

Here is a detailed comparison table for the common crystal categories:

Crystal CategoryKey FeaturesApplicationsTransparency Range (if applicable)
Nonlinear CrystalEnable frequency conversion, harmonic generation, and parametric amplification.Nonlinear optics, telecommunications, medical lasers.0.2 – 18 µm (varies by material).
Laser CrystalsProvide optical gain, excellent thermal properties, and high damage thresholds.Industrial, medical, scientific laser systems.0.2 – 2.1 µm
Magneto-Optical CrystalsFacilitate polarization control with high Faraday rotation and low absorption.Laser isolators, circulators, optical communication.0.4 – 2.0 µm
Birefringent CrystalsHigh birefringence for polarization optics, waveplates, and polarizers.Polarization optics, beam splitters, interferometry.0.3 – 2.1 µm
Raman CrystalsSupport Raman scattering processes for wavelength conversion and spectroscopy.Raman lasers, wavelength conversion, analytical spectroscopy.0.2 – 1.0 µm
Infrared CrystalsCover mid-IR to far-IR transparency for thermal imaging and laser systems.Thermal imaging, spectroscopy, laser guidance systems.2.5 – 25 µm
Athermal CrystalsMaintain optical stability across wide temperature ranges.Aerospace, defense, high-precision optical systems.Variable, designed for thermal stability
Q-Switching CrystalsEfficiently modulate laser pulses in high-power applications.High-power laser cutting, marking, medical lasers.Visible to NIR range
Scintillation CrystalsConvert radiation to visible light with high energy efficiency.Radiation detection in medical imaging, security.0.3 – 2.5 µm
Terahertz CrystalsGenerate or detect THz radiation for spectroscopy, imaging, and communication.THz spectroscopy, imaging systems, wireless communications.0.1 – 10 THz

 

Optical Crystals

Optical crystals are specialized materials with properties that enable light manipulation, amplification, or transmission with minimal loss. They are the cornerstone of photonic applications in industries such as telecommunications, healthcare, and scientific research. Below is a detailed overview of various types of optical crystals available in the library.
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Nonlinear Crystals

Nonlinear crystals are Photonics Crystal materials that exhibit non-linear optical properties, making them essential for frequency conversion processes such as second harmonic generation (SHG), optical parametric oscillation (OPO), and sum-frequency generation (SFG). These processes allow users to change laser wavelengths and expand their application ranges. Common nonlinear crystals include Beta Barium Borate (BBO) and Lithium Triborate (LBO). BBO is favored for its wide transparency range (190nm–3500nm) and high damage threshold, making it ideal for ultrafast pulse lasers. LBO, on the other hand, is known for its exceptional thermal stability, making it a popular choice in high-power laser systems. Nonlinear crystals are indispensable in applications such as laser spectroscopy, laser machining, and advanced medical imaging systems.
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Laser Crystals

Laser crystals are optical crystals used as the gain medium in solid-state lasers. These crystals are doped with rare-earth ions like neodymium (Nd), ytterbium (Yb), or erbium (Er) to provide the necessary energy states for light amplification. Popular examples include Neodymium-doped Yttrium Aluminum Garnet (Nd:YAG) and Ytterbium-doped YAG (Yb:YAG). Nd:YAG is widely used in industrial and medical lasers due to its high efficiency and ability to emit light at 1064nm. Yb:YAG, with its lower thermal loading, is ideal for high-energy, high-repetition-rate laser applications. Laser crystals are critical for applications such as material processing, laser cutting, and high-precision surgeries.
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Magneto-Optical Crystals

Magneto-optical crystals are Photonics Crystal materials that exhibit the Faraday effect, where the polarization plane of light rotates under the influence of a magnetic field. These crystals are widely used in isolators, circulators, and modulators to control and manipulate light in optical communication and laser systems. Terbium Gallium Garnet (TGG) is a commonly used magneto-optical crystal, known for its high Verdet constant, excellent thermal conductivity, and low optical loss. These properties make it ideal for high-power laser isolators and advanced optical systems. Applications for magneto-optical crystals range from laser stabilization to fiber-optic communications and optical instrumentation.
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Raman Crystals

Raman crystals are used in Raman lasers and amplifiers, exploiting the Raman scattering effect to shift the wavelength of light. These crystals are key to applications that require wavelength conversion and laser frequency stabilization. A notable example is Barium Tungstate (BaWO4), which exhibits a high Raman gain coefficient and excellent optical properties. Raman crystals find applications in spectroscopy, laser medicine, and quantum optics.
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Infrared Crystals

Infrared (IR) crystals are designed for applications in the infrared spectrum, typically ranging from 1μm to 20μm. These crystals are critical in thermal imaging, infrared spectroscopy, and laser systems. Common infrared crystals include Zinc Selenide (ZnSe) and Germanium (Ge). ZnSe is widely used in CO2 lasers and IR optics due to its broad transparency range and low absorption. Germanium, with its high refractive index and excellent transmission in the 2–12μm range, is ideal for thermal imaging and night vision systems.
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Athermal Crystals

Athermal crystals are Photonics Crystal materials designed to minimize thermal effects, maintaining consistent optical performance under varying temperature conditions. They are crucial in environments where temperature stability is critical. Examples include Calcium Fluoride (CaF2), which offers low thermal expansion and high optical clarity, making it suitable for high-precision optical systems such as telescopes, lasers, and spectrometers.
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Q-Switching Crystals

Q-switching crystals are used in laser systems to produce short, intense pulses of light. These crystals enable controlled energy buildup within a laser cavity, resulting in high peak power outputs. Cr:YAG (Chromium-doped YAG) is a widely used Q-switching crystal due to its high damage threshold and stable performance. Applications include medical lasers, micromachining, and laser rangefinders.
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Scintillation Crystals

Scintillation crystals are used in radiation detection and imaging systems. They emit light when exposed to high-energy particles, making them essential in applications such as medical imaging, nuclear physics, and security screening. Cesium Iodide (CsI) and Bismuth Germanate (BGO) are popular choices. CsI offers high light yield and fast response times, making it ideal for X-ray imaging and gamma-ray detection. BGO, with its high density and excellent energy resolution, is widely used in PET scanners and other high-resolution imaging systems.
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CVD (Chemical Vapor Deposition) diamonds

VD (Chemical Vapor Deposition) diamonds are advanced synthetic materials known for their exceptional optical, thermal, and mechanical properties, making them indispensable in a wide range of high-tech applications. These diamonds are created through a controlled deposition process that produces high-purity, high-performance crystals with unique features. CVD diamonds are highly valued for their outstanding thermal conductivity, optical transparency across UV to IR wavelengths, and extraordinary hardness. Different types of CVD diamonds serve specific purposes: Optical Grade Polycrystalline and Single Crystal Diamonds are ideal for high-power laser optics, IR windows, and Raman spectroscopy; Raman Diamonds enhance sensitivity and resolution in spectroscopy systems; Color Center Diamonds, with engineered defects such as nitrogen-vacancy (NV) centers, are critical for quantum computing and advanced photonic circuits;
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Terahertz Crystals

Terahertz crystals are designed for applications in the terahertz frequency range (0.1–10THz), such as terahertz imaging, spectroscopy, and communication systems. Gallium Phosphide (GaP) and Lithium Niobate (LiNbO3) are commonly used terahertz crystals. GaP, with its excellent nonlinear optical properties, is ideal for generating and detecting terahertz waves. LiNbO3 is often used in terahertz waveguides and modulators due to its high electro-optic coefficient.
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The Photonics Crystal Library at POC is your ultimate guide to understanding and selecting the right photonic crystals for your needs. Each crystal type is described in detail to help you make informed decisions based on your application requirements. Explore our library to discover innovative solutions for your photonics projects. Contact us today to learn more or request a consultation with our experts!