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Distributed-feedback laser (DFB)
Optical Amplifiers
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Tunable Sources
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Broadband Light Sources
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Multimode Laser Diodes
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1080 nm Laser Diodes

1080 nm Laser Diodes

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1080 nm Laser Diodes

Wavelengths of 1080 nanometers are essential across scientific, industrial, and medical applications, enabling high-power laser systems, precision materials processing, and advanced imaging. Known for efficiency and stability, 1080 nm lasers are indispensable in environments that require consistent, high-performance light sources.

Applications of 1080 nm Laser Diodes

In industrial settings, 1080 nm ytterbium-doped fiber and solid-state lasers are pivotal for high-power operations such as cutting, welding, and precision shaping. The efficient energy absorption in ytterbium media at this wavelength allows for stable, high-intensity beams, ideal for rigorous manufacturing tasks. In fiber laser systems, 1080 nm sources like SM-1080 are key for seeding, pumping, and amplification in master oscillator power amplifier setups, delivering the output stability and spectral purity needed for demanding applications. In medical imaging, 1080 nm lasers support high-resolution systems, including optical coherence tomography (OCT) and microscopy for detailed sample examination. Their deep tissue penetration with low scattering enhances clarity in fields like ophthalmology and dermatology. Additionally, 1080 nm lasers are used in photothermal therapy, where controlled energy enables targeted treatments with minimal surrounding tissue impact. For scientific research, 1080 nm sources are vital in spectroscopy for high-resolution molecular analysis and gas detection, where narrow linewidth and spectral precision are critical. These lasers are also crucial for fiber pumping, boosting signal amplification over long distances and supporting advanced sensing systems.

Types of Light Sources: Laser diodes at 1080 nm provide narrow-linewidth, coherent light suitable for precision tasks in spectroscopy, fiber laser seeding, and materials processing. Femtosecond and picosecond lasers at this wavelength offer ultrafast pulses for high-speed measurements in dynamic imaging and research. Superluminescent diodes with broad-spectrum, low-coherence output are ideal for OCT and microscopy, enhancing clarity by reducing speckle noise. Semiconductor optical amplifiers at 1080 nm enable scalable power and rapid modulation, supporting high-demand scientific and industrial environments.

Technical Advantages: Engineered for compactness, energy efficiency, and adaptability, 1080 nm laser devices feature options like polarization-maintaining fibers, tunable wavelengths, and external cavity setups. Precision temperature and current control ensures stable, high-accuracy output, making these lasers ideal for OCT, spectroscopy, industrial processing, and photothermal therapy. The robustness and flexibility of 1080 nm sources position them as essential tools in high-performance, precision-driven applications.