Working characteristics of external distributed feedback polymer lasers with varying waveguiding structures

We report the fabrication and characterization of second-order external distributed feedback (DFB) lasers based on blue-emitting polymer poly (9, 9-dioctyl-fluorene) (PFO). The relief grating prepared in the photo-resist layer on top of the gain medium was directly employed as the resonator. The eff...

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Bibliographic Details
Published in:Journal of physics. D, Applied physics Applied physics, 2015-12, Vol.48 (49), p.495105-495115
Main Authors: Huang, Wenbin, Shen, Su, Pu, Donglin, Wei, Guojun, Ye, Yan, Peng, Changsi, Chen, Linsen
Format: Article
Language:English
Subjects:
Amplification
distributed feedback laser
Feedback
Gain
Lasers
Lasing
organic semiconductor
Organic semiconductors
Residues
Thresholds
waveguide
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Summary:We report the fabrication and characterization of second-order external distributed feedback (DFB) lasers based on blue-emitting polymer poly (9, 9-dioctyl-fluorene) (PFO). The relief grating prepared in the photo-resist layer on top of the gain medium was directly employed as the resonator. The effect of various structural parameters including the thickness of the active film, the thickness of the residue layer, and the depth of the relief grating on performance of these polymer lasers was investigated. An analytical approach based on the slab waveguiding theory and the Bragg condition was developed to accurately determine the lasing wavelength. We found that laser threshold increases monotonously as the thickness of the residue layer increases. The presence of the residue layer between the relief grating and the organic semiconductor layer weakens the strength of light coupling between the two layers, leading to a decreased gain for the specific lasing mode. The lowest laser threshold level of 80 μJ cm−2 was obtained when the thickness of the gain medium was around 250 nm, indicating an optimum balance between light feedback provided by the grating and optical amplification in the organic semiconductor. Our results not only provide insights into working mechanisms of external DFB polymer lasers, but also design rules for fabricating them.
ISSN:0022-3727
1361-6463
DOI:10.1088/0022-3727/48/49/495105