Abstract
In recent years, conjugated polymers have become the materials of choice to fabricate optoelectronic devices, owing to their properties of high absorbance, high quantum efficiency, and wide luminescence tuning ranges. The efficient feedback mechanism in the concentric ring resonator and its circularly symmetric periodic geometry combined with the broadband photoluminescence spectrum of the conjugated polymer can generate a highly coherent output beam. Here, the detailed design of the ultralow-threshold single-mode circular distributed feedback polymer laser is presented with combined fabrication processes such as electron beam lithography and the spin-coating technique. We observe from the extinction spectra of the circular gratings that the transverse electric mode shows no change with the increase of incident beam angle. The strong enhancement of the conjugated polymer photoluminescence spectra with the circular periodic resonator can reduce the lasing threshold about 19 µJ/cm2. A very thin polymer film of about 110 nm is achieved with the spin-coating technique. The thickness of the gain medium can support only the zero-order transverse electric lasing mode. We expect that such a low threshold lasing device can find application in optoelectronic devices.
Highlights
IntroductionIn organic semiconductors, conjugated polymers have magnificent optical and electrical properties, broad photoluminescence (PL) spectral in the visible region, lost-cost processing, and easy fabrication methods on the flexible substrates [3,10,11,12,13]
In recent years, conjugated polymers have been extensively applied as gain mediums in laser systems with different optical feedback nanostructures, such as whispering gallery mode (WGM)[16,17], microdroplet [18], and distributed feedback (DFB) cavities [19,20,21,22,23]
We focus on the morphology and lasing performance of optically pumped surface-emitting circular DFB polymer laser
Summary
In organic semiconductors, conjugated polymers have magnificent optical and electrical properties, broad photoluminescence (PL) spectral in the visible region, lost-cost processing, and easy fabrication methods on the flexible substrates [3,10,11,12,13]. All these unique and intriguing features of the conjugated polymers provide a new route to explore optoelectronic technologies and micro-cavity lasers [14,15].
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