Gain module Nd:YAG laser rod dia 15mm x 135mm
Spec: gain module nd:yag laser rod dia 15mmx135mm, qcw, generation
power max 16j at 2ms pulses, 10hz, damage threshold>10j/cm^2 at
1064nm, 10ns pulses
Pulsed diode-pumped Nd:YAG laser gain modules, which amplify light in solid-state lasers, are utilized in systems like MOPA setups for diverse applications. These modules often require water cooling to manage heat generated during operation.
אתם מוזמנים ליצור עימנו קשר לגבי מוצר זה לקבלת פרטים נוספים, ייעוץ והצעת מחיר
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Other options:
gain module with nd:yag laser rod dia 4mmx165mm, qcw generation
energy max 5.5j at pulses 2ms, 10Hz, damage threshold>10j/cm^2
at 1064nm/10ns pulses
gain module, nd:yag laser rod dia 9mmx180mm, qcw max generation
energy 11j at pulse duration 2ms, 10hz, damage threshold>10j/cm^2
at 1064nm/10ns pulses
Tags: Custom Pulsed Laser Gain Modules Nd:YAG, Diode pumped Nd:YAG gain module, Gain module Nd:YAG laser rod dia 15mm x 135mm, High power Nd:YAG gain module, Higher power diode pumped Nd:YAG laser gain modules, Laser Gain Modules, laser rods, Nd:YAG gain module, Nd:YAG laser amplifier module, Nd:YAG laser rod amplifier, Nd:YAG laser rod gain module, Pulsed diode-pumped Nd:YAG laser gain modules, Pulsed Nd:YAG gain module
Here are 10 products similar to an Nd:YAG laser rod gain module that are in top demand today, reflecting modern advancements in laser technology.
1. Diode-Pumped Solid-State (DPSS) Laser Modules
This is the modern equivalent of the lamp-pumped Nd:YAG system. These integrated modules use high-power laser diodes to pump the Nd:YAG crystal, offering superior efficiency, a longer lifetime, and a much smaller footprint. They are the most common type of solid-state laser module in industrial and medical applications today.
2. Ytterbium-doped YAG (Yb:YAG) Crystals
Yb:YAG has largely replaced Nd:YAG for high-power industrial applications like cutting and welding. It has a much lower thermal load, a broader absorption bandwidth, and a longer fluorescence lifetime, making it more efficient and suitable for high-power diode pumping.
3. Nd:YVO4 Laser Crystals
Neodymium-doped Yttrium Orthovanadate (Nd:YVO4) is a gain medium with a very large stimulated emission cross-section. This property makes it excellent for compact, low-power, and single-frequency lasers, which are used in applications requiring high beam quality, such as laser marking and micromachining.
4. Nd:YLF Laser Crystals
Neodymium-doped Lithium Yttrium Fluoride (Nd:YLF) is a crystal with a longer fluorescence lifetime than Nd:YAG. This makes it a preferred choice for Q-switched lasers that need to store more energy for high-energy pulses. It is often used in medical and scientific research.
5. Erbium-doped YAG (Er:YAG) Crystals
Operating at a wavelength of 2940 nm, these crystals are highly absorbed by water. This makes them a top choice for medical applications like dentistry and dermatology, where precise ablation of water-rich tissue is required with minimal thermal damage to surrounding areas.
6. Ceramic Nd:YAG Rods
Unlike the traditional single-crystal Nd:YAG, ceramic versions are made by sintering. They offer advantages like the ability to be fabricated in larger sizes and more complex shapes, and they have excellent optical homogeneity. This makes them a strong contender for very high-power lasers and custom designs.
7. Thin-Disk Laser Gain Modules
This technology uses a very thin crystal disk (often Yb:YAG) as the gain medium. This design provides a large surface area for heat dissipation, allowing for extremely high output power with excellent beam quality. Thin-disk lasers are in high demand for high-power industrial applications.
8. Fiber Laser Gain Modules
Fiber lasers are a major competitor to solid-state lasers. These modules consist of an optical fiber (often ytterbium- or erbium-doped) that acts as the gain medium. They are known for their high efficiency, compact size, and reliability, and are now the dominant technology in many industrial material processing sectors.
9. Nd:Glass Laser Slabs
Neodymium-doped glass is a medium used for extremely high-energy, pulsed lasers. While it has lower thermal conductivity than crystals, it can be manufactured in very large sizes and at a lower cost, making it the gain medium of choice for applications like inertial confinement fusion research.
10. Titanium-doped Sapphire (Ti:Sapphire) Crystals
While not a direct substitute for Nd:YAG in terms of wavelength, Ti:Sapphire crystals are the most common gain medium for tunable, ultrafast lasers. They are in top demand for scientific research, spectroscopy, and advanced medical imaging due to their ability to generate ultrashort pulses.
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