Hydrogel optical fiber random laser

Hydrogel materials have great applications in biomedical and flexible optical sensors due to their good flexibility and biocompatibility. In this paper, two hydrogel structures of dye-doped poly(acrylamide-co-poly(ethylene glycol) diacrylate) (p(AM-co-PEGDA)) films and optical fibers were prepared to obtain low threshold and flexible random lasers. The random laser is attributed to the light scattering from the porous structure of the hydrogel, and the random lasing wavelength can be tuned of -7 nm and -11.8 nm for the hydrogel film and fiber in the temperature range of 25 to 85 degrees C, respectively. In addition, the hydrogel film can be bent repeatedly, and the bending strain has a positive effect on the random laser, and the random laser threshold is reduced by 10 mu J/mm2 when the bending strain reaches 47 % for hydrogel film. When the hydrogel optical fiber is stretched to 15 % of its original length, the random laser threshold can be reduced by 12 mu J/mm2.The p(AM-co-PEGDA) hydrogel optical fiber structure has better temperature sensing performance and excellent flexibility than the thin film structure. This work paves a way to extend random laser applications to photothermal therapy, ion detection, and biosensing.

Automated summary

This paper investigates the use of hydrogel materials in biomedical and flexible optical sensors. Two hydrogel structures, film and fiber, were prepared to achieve low threshold and flexible random lasers. The random laser is attributed to light scattering from the porous structure of the hydrogel. The hydrogel film and fiber showed tunable random lasing wavelengths within a temperature range. The bending strain and stretching of the hydrogel structures also influenced the random laser threshold. The hydrogel fiber structure exhibited better temperature sensing performance and flexibility compared to the thin film structure. This research opens up possibilities for the application of random lasers in photothermal therapy, ion detection, and biosensing.