Lamp-Pumped

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LNF Series OEM Laser Head Nd:YAG 1064nm

LNF Series OEM Laser Head Nd:YAG 1064nm

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Sold by: VIGITEK, INC. Ships from: United States
Specifications
Max Input Power: 3.5 kW
Max Output Power: 70W
Medium/Min Flow: Water/4.7 lpm
Operation Temperature: +10…+40°C
Storage Temperature: -40…+85°C
LNF Series OEM Laser Head Nd:YAP1340nm

LNF Series OEM Laser Head Nd:YAP1340nm

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Sold by: VIGITEK, INC. Ships from: United States
Specifications
Medium/Min Flow: Water/4.7 lpm
Operation Temperature: +10…+40°C
Storage Temperature: -40…+85°C
Humidity: 90%, non-condensing
Size (LxWxH): 385x50x59 mm
LNF Series OEM Laser Head Er:YAG 2940nm

LNF Series OEM Laser Head Er:YAG 2940nm

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Sold by: VIGITEK, INC. Ships from: United States
Specifications
Max. Input Power: 3.5 kW
Medium/Min. Flow: Water/4.7 lpm
Slope Efficiency: 4.5%
Spot Size: 7 mm
Max Outpu Power: 15 W
Litron Nano TRL 425-10 PIV

Litron Nano TRL 425-10 PIV

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Sold by: Litron Lasers Ships from: United Kingdom
Litron Bernoulli B-PIV 200-15

Litron Bernoulli B-PIV 200-15

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Sold by: Litron Lasers Ships from: United Kingdom
Litron Nano L 145-15 PIV

Litron Nano L 145-15 PIV

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Sold by: Litron Lasers Ships from: United Kingdom
Litron Nano L 200-15 PIV

Litron Nano L 200-15 PIV

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Sold by: Litron Lasers Ships from: United Kingdom
Litron TRL 325-15 PIV

Litron TRL 325-15 PIV

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Sold by: Litron Lasers Ships from: United Kingdom
Nano S 120-20 Laser

Nano S 120-20 Laser

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Sold by: Litron Lasers Ships from: United Kingdom
Specifications
Optional Wavelengths: 532nm, 355nm, 266nm, 213nm
Nano S 130-10 Laser

Nano S 130-10 Laser

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Sold by: Litron Lasers Ships from: United Kingdom
Specifications
Optional Wavelengths: 1064nm, 355nm, 266nm, 213nm
High Energy Nanosecond Nd:Glass LASER

High Energy Nanosecond Nd:Glass LASER

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Sold by: Geola Digital Ltd Ships from: Lithuania
Specifications
Wavelength: 1053 / 526.5 / 351 / 263 nm
Pulse Energy (max): up to 4 J / up to 15 J
Typical Pulse Duration: ~25 ns
Pulse To Pulse Energy Stability: ≤5 % RMS
Pulse Repetition Period: 2 min / 3 min
Pulsed Nd:YAG Lasers Model LQ529

Pulsed Nd:YAG Lasers Model LQ529

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Sold by: SOLAR Laser Systems Ships from: Belarus
Specifications
Wavelength: 532 nm
Pulse Energy: 280 mJ
Pulse Energy Stability: 1.5 %
Pulse Duration: 10 ns
Repetition Rate: 1 – 30 Hz
EverGreen ² (70-200 mJ @ 532 nm)

EverGreen ² (70-200 mJ @ 532 nm)

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Sold by: Lumibird Ships from: France
Specifications
Beam Divergence : < 4 mrad
Shot To Shot Pointing Stability: < 100 µrad
EverGreen ²

EverGreen ²

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Sold by: Quantel Laser by Lumibird Ships from: France
Specifications
Shot To Shot Pointing Stability: < 100 µrad
Beam Divergence: < 4 mrad
Q-smart 850

Q-smart 850

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Sold by: Quantel Laser by Lumibird Ships from: France
Q-smart (850 mJ)

Q-smart (850 mJ)

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Sold by: Lumibird Ships from: France

Did You Know?

The first working laser, constructed by Theodore Maiman in 1960, was a ruby laser pumped with a flash lamp. Lamp-pumped lasers utilize laser pumping as the act of energy transfer from an external source into the gain medium of a laser. They are commonly used for applications demanding higher energies, as lamp-pumped lasers are able to generate very high pump powers. Additionally, lamp-pumped lasers offer low price per watt of generated power compared to laser diodes. They are also relatively sturdy and can handle voltage and current spikes.
Read more in our Blog

Related Resources

Lamp-Pumped Solid-State Lasers: High-Energy Light Sources for Diverse Applications

Lamp-pumped solid-state lasers are a category of lasers that utilize optical pumping via flashlamps or arc lamps to excite the gain medium, typically a crystalline or glass host doped with rare-earth ions such as neodymium (Nd), ytterbium (Yb), or praseodymium (Pr). This pumping method has been foundational in the development of high-power laser systems, especially before the advent of diode-pumped technologies.

Operating Principles

In lamp-pumped solid-state lasers, the pump source—either a flashlamp or an arc lamp—emits broad-spectrum light that is absorbed by the dopant ions in the gain medium. The excited ions then undergo radiative transitions, emitting coherent light at specific wavelengths. The design of the laser cavity, including the use of mirrors and optical coatings, helps to direct and amplify the emitted light, resulting in a high-intensity laser beam.

Advantages

  • High Pulse Energy: Lamp-pumped lasers can deliver high pulse energies, making them suitable for applications requiring intense light pulses.

  • Established Technology: The technology is well-understood and has been used in various applications for decades.

  • Cost-Effectiveness: Compared to diode-pumped systems, lamp-pumped lasers can be more cost-effective, especially for high-power applications.

Applications

  • Materials Processing: Used in cutting, welding, and engraving due to their high pulse energies.

  • Medical Procedures: Employed in certain surgical applications where high-intensity light is required.

  • Scientific Research: Utilized in spectroscopy and other research areas that require high-energy light sources.

Considerations

While lamp-pumped solid-state lasers offer high pulse energies, they also come with considerations such as lower efficiency and shorter lifespans of the pump sources compared to diode-pumped systems. Additionally, the broad emission spectrum of the pump sources can lead to thermal effects and spectral broadening in the output beam. Advancements in diode-pumped technology have addressed some of these issues, offering higher efficiency and more stable output.

Conclusion

Lamp-pumped solid-state lasers remain a vital technology in areas where high pulse energy and cost-effectiveness are paramount. Their continued use in various applications underscores their importance in the field of laser technology.