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A 1150-W 1018-nm Fiber Laser Bidirectional Pumped by Wavelength-Stabilized Laser Diodes | IEEE Journals & Magazine | IEEE Xplore

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A 1150-W 1018-nm Fiber Laser Bidirectional Pumped by Wavelength-Stabilized Laser Diodes

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Abstract:

This paper presented a high-power 1018-nm ytterbium-doped fiber laser pumped by wavelength-stabilized laser diodes in bidirectional pumping structure. A record output pow...Show More

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Abstract:

This paper presented a high-power 1018-nm ytterbium-doped fiber laser pumped by wavelength-stabilized laser diodes in bidirectional pumping structure. A record output power reaching 1150 W was achieved, along with a slope efficiency of 82.9% and a beam quality factor of M² = 1.96. The output spectrum exhibited an efficient amplified spontaneous emission and parasitic lasing light suppression. The thermal effects were studied to verify the reliability of our 1018-nm FL as a practical 1-kW light source. Besides, an important investigation was made on the 1080-nm fiber laser tandem pumped by 1018-nm fiber lasers, the experimental result of which was reported to be 3712 W.

Published in: IEEE Journal of Selected Topics in Quantum Electronics ( Volume: 24, Issue: 3, May-June 2018)

Article Sequence Number: 0902506

Date of Publication: 19 February 2018

ISSN Information:

DOI: 10.1109/JSTQE.2018.2805801

Funding Agency:

References is not available for this document.

I. Introduction

Nowadays high power fiber lasers (FLs) with their outstanding advantages have been widely used in many industrial, military and scientific applications [1]– [3]. For a FL, the pumping configuration is of critical importance, which can be divided into two major categories: direct-pumping configuration [4], [5] and tandem-pumping configuration [6] , [7]. As far as we know, the highest power of single output fiber was reported by IPG in 2009 based on the tandem-pumping, taking advantage of the relatively short wavelength (1000–1030 nm) FLs employed as the pump source in tandem-pumping to reduce the quantum defect in the active fiber, which leads to less thermal load and larger pumping capacity [8]. Hence, the tandem-pumped FLs have the potential to raise the output power limit [9] . Consequently, rising attention has been paid by researchers worldwide to achieve higher output power of these short wavelength FLs, especially 1018 nm ytterbium-doped fiber laser (YDFLs) [10]–[14].

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References is not available for this document.