QC120 ULTRACOMPACT Q-SWITCHED MICROCHIP LASER
Description
SOLAR LS offers a family of passive Q-switched microlasers. The QC series lasers are diode-pumped solid-state lasers operating at 1540 nm and 1064 nm 532 nm, 355 nm, 266 nm.
Non-misalignable monolithic cavity guarantees reliability of operation and extreme stability of laser parameters. Pulse duration of ~1 ns ensures high peak power which in combination with ideal beam quality makes these lasers an indispensable instrument for a variety of scientific tasks. The extremely reliable and robust design of these lasers makes them the best choice for industrial applications.
Compact footprint, external triggering and pumping via an optical fiber not only simplify application of these devices as stand-alone units but also allow to easily integrate them into any equipment. The lifetime of more than 109 pulses minimises your service costs.
QC120 ULTRACOMPACT Q-SWITCHED MICROCHIP LASER
Specifications |
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Avg. Power: | 0.2 W |
Wavelength: | 532 nm |
Repetition Rate: | 0.1-0.3kHz |
Spatial Mode (M^2): | 1.5 |
Pulse Duration: | 0.9 ns |
Pulse-to-Pulse Stability (RMS): | -- % |
Cooling: | Air |
Features
- Compact and dustproof design
- 1540 nm, 1064 nm, 532 nm, 355 nm, 266 nm
- Output energy up to 500 µJ
- Peak power up to 500 kW
- Lifetime of more than 109 pulses
- ТЕМ00
Applications
- Micromachining and materials processing
- Time-resolved fluorescence
- Nonlinear optics
- Laser ignition
- LIDAR
- LIBS
For pricing, technical or any other questions please contact the supplier
- No registration required
- No markups, no fees
- Direct contact with supplier
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Ships from:
Belarus
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Sold by:
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On FindLight:
since 2019
Frequently Asked Questions
The QC series lasers operate at 1540 nm, 1064 nm, 532 nm, 355 nm, and 266 nm.
The pulse duration is approximately 1 ns.
The peak power can reach up to 500 kW.
The QC series lasers can be used for micromachining and materials processing, time-resolved fluorescence, nonlinear optics, laser ignition, LIDAR, and LIBS.
The lifetime is more than 10^9 pulses, which minimizes service costs.