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Chromium-doped Yttrium Aluminum Garnet Cr:YAG Ce+ Doped Yag Laser Crystal Laser Systems
Product Details:
| Place of Origin: | China |
| Brand Name: | ZMSH |
| Model Number: | YAG |
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Detail Information |
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| Chemical Formula: | Y3Al5O12 | The Crystal Structure: | Cubic Crystal System |
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| Lattice Parameters: | 12.01 | Melting Point: | 1970°C |
| The Density: | 4.5g/cm3 | Reflectivity: | 1.82 |
| Coefficient Of Thermal Expansion: | 7.8x10-6 /K <111>,0 - 250 OC | Thermal Conductivity: | 14W/m/K, 20°C;10.5W/m/K, 100°C |
| Mohs Hardness: | 8.5 | Stimulated Emission Cross Section: | 2.8x10-19 Cm-2 |
| Loss Coefficient: | 0.003 Cm-1 @ 1064nm | Line Width: | 0.6 Nm |
| Radiation Life: | 550 Ms | ||
| High Light: | Chromium-doped Yttrium Aluminum Garnet crystal,yag Cr:YAG Laser crystal |
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Product Description
Chromium-doped Yttrium Aluminum Garnet Cr:YAG ce+ doped yag laser crystal Laser Systems
ce+ doped yag laser crystal's abstract
Cerium-doped yttrium aluminum garnet (Ce:YAG) crystal has garnered significant attention as a versatile laser material with a wide range of applications in various fields. This abstract aims to provide a concise overview of the key characteristics and applications of Ce:YAG laser crystals.
Ce:YAG crystals belong to the family of rare-earth-doped laser materials, where the incorporation of cerium ions into the YAG crystal lattice plays a pivotal role in enabling laser emission. The unique spectroscopic properties of cerium ions, such as broad absorption bands and efficient energy transfer mechanisms, contribute to the exceptional performance of Ce:YAG as a laser medium.
One of the remarkable features of Ce:YAG crystals is their broad absorption band, which allows efficient absorption of pump radiation from diverse laser sources, including flashlamps, diode lasers, and fiber lasers. This broad absorption bandwidth enhances the flexibility and compatibility of Ce:YAG crystals with different pumping schemes, making them suitable for various laser configurations and applications.
Moreover, Ce:YAG crystals exhibit high optical homogeneity, excellent thermal conductivity, and good mechanical properties, enabling stable and efficient laser operation under demanding conditions. These characteristics make Ce:YAG crystals well-suited for high-power and high-energy laser systems, as well as for applications requiring precise wavelength control and narrow linewidths.
Ce:YAG lasers find widespread use in numerous fields, including medical, industrial, defense, and scientific applications. In medicine, Ce:YAG lasers are employed for dermatological procedures, dental treatments, and ophthalmic surgeries. In industry, they are utilized for materials processing, laser marking, and micromachining. In defense and scientific research, Ce:YAG lasers serve in lidar systems, spectroscopy, and nonlinear optics experiments.
In conclusion, Cerium-doped yttrium aluminum garnet (Ce:YAG) crystals represent a valuable class of laser materials characterized by their broad absorption bandwidth, excellent optical and thermal properties, and versatile applications across diverse fields. Their unique combination of features makes them indispensable for advancing laser technology and addressing a wide range of scientific, medical, and industrial challenges.
ce+ doped yag laser crystal's showcase
ce+ doped yag laser crystal's application
Cerium-doped yttrium aluminum garnet (Ce:YAG) laser crystals find a variety of applications across different fields due to their unique optical properties and versatility. Some of the key applications of Ce:YAG laser crystals include:
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Solid-State Lasers: Ce:YAG crystals are commonly used as gain media in solid-state lasers. They can be pumped by various sources such as flashlamps, diode lasers, or other solid-state lasers. Ce:YAG lasers emit in the near-infrared region and can be frequency-doubled or frequency-tripled to generate visible or ultraviolet wavelengths, making them useful for a wide range of applications.
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Medical Lasers: Ce:YAG lasers are extensively used in medical applications, particularly in dermatology, ophthalmology, and dentistry. They are employed for procedures such as skin resurfacing, tattoo removal, treatment of vascular lesions and pigmented lesions, as well as various ophthalmic surgeries and dental procedures due to their precise tissue interaction and minimal thermal damage.
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Laser Range Finding and Targeting: Ce:YAG lasers are utilized in laser rangefinders and targeting systems due to their ability to produce high-energy pulses with excellent beam quality and stability. These lasers are essential in military and defense applications for accurate distance measurement, target designation, and guidance systems.
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Laser Pumping: Ce:YAG crystals serve as efficient pump sources for other laser materials, such as chromium-doped crystals (e.g., Cr:YAG) or neodymium-doped crystals (e.g., Nd:YAG). By providing high pump efficiency and broad absorption bandwidth, Ce:YAG lasers enable the efficient operation of various solid-state and fiber lasers.
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Material Processing and Micromachining: Ce:YAG lasers are employed in industrial applications for cutting, drilling, welding, and marking of various materials, including metals, ceramics, and polymers. Their high peak power, short pulse duration, and excellent beam quality make them suitable for precision machining tasks in manufacturing and fabrication processes.
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Scientific Research: Ce:YAG lasers are utilized in various scientific research applications, including spectroscopy, nonlinear optics, and laser-induced fluorescence studies. Their tunable output wavelengths, narrow linewidths, and high pulse energies make them valuable tools for investigating fundamental physical and chemical processes in laboratory settings.
Overall, Ce:YAG laser crystals play a critical role in advancing laser technology and addressing diverse applications in medicine, industry, defense, and scientific research, owing to their excellent optical performance, reliability, and versatility.
ce+ doped yag laser crystal's properties
Cerium-doped yttrium aluminum garnet (Ce:YAG) laser crystals possess several key properties that make them highly suitable for various laser applications. Some of the primary properties of Ce:YAG crystals include:
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Broad Absorption Band: Ce:YAG crystals exhibit a broad absorption band in the visible and near-infrared spectral regions. This characteristic enables efficient absorption of pump radiation from a wide range of laser sources, including flashlamps, diode lasers, and fiber lasers, facilitating effective energy transfer and laser operation.
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High Thermal Conductivity: Ce:YAG crystals have high thermal conductivity, allowing them to efficiently dissipate heat generated during laser operation. This property helps in maintaining stable laser performance, reducing thermal effects, and preventing thermal damage to the crystal, even at high pump powers and repetition rates.
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Excellent Optical Quality: Ce:YAG crystals exhibit high optical homogeneity, low scattering losses, and minimal optical defects, ensuring high-quality laser beams with low divergence and excellent beam profile. This property is essential for achieving high laser efficiency, good beam pointing stability, and precise laser processing in various applications.
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Stable and Robust: Ce:YAG crystals are chemically stable and mechanically robust, making them suitable for long-term use in laser systems operating under demanding conditions. They can withstand thermal cycling, mechanical stress, and exposure to harsh environmental conditions without significant degradation in performance, ensuring reliable and consistent laser operation over time.
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Tunable Wavelengths: Ce:YAG crystals allow for the generation of tunable laser wavelengths within the near-infrared spectral range. By adjusting the laser cavity configuration or using intracavity elements, such as etalons or optical filters, Ce:YAG lasers can produce output wavelengths tailored to specific applications, enhancing their versatility and utility in various laser systems.
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High Efficiency: Ce:YAG crystals exhibit high conversion efficiency from pump energy to laser output, leading to efficient utilization of pump radiation and minimal heat generation. This property is crucial for achieving high overall laser efficiency, reducing power consumption, and maximizing output power in laser systems.
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Chemical formula Y3Al5O12 The crystal structure Cubic crystal system Lattice parameters 12.01? Melting point 1970°C The density 4.5g/cm3 reflectivity 1.82 Coefficient of thermal expansion 7.8x10-6 /K <111>,0 - 250 oC Thermal conductivity 14W/m/K, 20°C;10.5W/m/K, 100°C Mohs hardness 8.5 Stimulated emission cross section 2.8x10-19 cm-2 Loss coefficient 0.003 cm-1 @ 1064nm Line width 0.6 nm Radiation life 550 ms
Overall, the combination of these properties makes Ce:YAG laser crystals well-suited for a wide range of laser applications, including medical, industrial, scientific, and defense applications, where high-performance, reliability, and versatility are essential requirements.
Q&A
What is a YAG crystal?
Yttrium aluminium garnet (YAG, Y3Al5O12) is a synthetic crystalline material of the garnet group. It is a cubic yttrium aluminium oxide phase, with other examples being YAlO3 (YAP) in a hexagonal or an orthorhombic, perovskite-like form, and the monoclinic Y4Al2O9 (YAM).
What are the lattice parameters of YAG?
this caused the lattice parameters of YAGs to linearly expand from 12.0071(1) Å to 12.1354(1) Å. The presence of excess Y3+ at 16a site was also detected by STEM, at the atomic scale, by showing Z-contrast signal from HAADF imaging and intensity profile.