AI Article Synopsis
- Two-dimensional (2D) layered transition metal dichalcogenides (TMDs) have great nonlinear optical properties, making them valuable for optoelectronic applications like saturable absorbers in ultrafast photonics.
- WS was successfully used as a saturable absorber in erbium-doped fiber laser systems, demonstrating impressive nonlinear characteristics, including a modulation depth of 15.1% and saturable intensity of 157.6 MW cm.
- The study achieved remarkable soliton pulse generation with an ultrashort duration of 1.49 ps, high stability of 71.8 dB, and a large average output power of 62.5 mW, marking a significant advancement in utilizing TMD materials in fiber laser
Article Abstract
Two-dimensional (2D) layered transition metal dichalcogenides (TMDs) have attracted significant interest in various optoelectronic applications due to their excellent nonlinear optical properties. One of the most important applications of TMDs is to be employed as an extraordinary optical modulation material (e.g., the saturable absorber (SA)) in ultrafast photonics. The main challenge arises while embedding TMDs into fiber laser systems to generate ultrafast pulse trains and thus constraints their practical applications. Herein, few-layered WS with a large-area was directly transferred on the facet of the pigtail and acted as a SA for erbium-doped fiber laser (EDFL) systems. In our study, WS SA exhibited remarkable nonlinear optical properties (e.g., modulation depth of 15.1% and saturable intensity of 157.6 MW cm) and was used for ultrafast pulse generation. The soliton pulses with remarkable performances (e.g., ultrashort pulse duration of 1.49 ps, high stability of 71.8 dB, and large pulse average output power of 62.5 mW) could be obtained in a telecommunication band. To the best of our knowledge, the average output power of the mode-locked pulse trains is the highest by employing TMD materials in fiber laser systems. These results indicate that atomically large-area WS could be used as excellent optical modulation materials in ultrafast photonics.
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| http://dx.doi.org/10.1039/c6nr09183k | DOI Listing |
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