Abstract
We demonstrate high-quality on chip random lasing of the acceptor dye using a specially designed dynamic linear array of microdroplets with unconventional shapes that do not support the whispering gallery modes. The intrinsic disorder in the droplet array consequent to its dynamic nature is utilized in achieving the randomness in the lasing emission without deliberately adding the disorder as in ordinary random laser systems. The novelty of the generated structure is illustrated by comparing its emission characteristics with two other arrays made of microspheres and microtriangular droplets arranged in a zig zag fashion. We show that only the linear array of microdroplets supports lasing in the acceptor emission. The design of the array structure allows to further reduce the lasing threshold drastically either by incorporating the radiative energy transfer or by tuning the number of acceptor dye molecules. The highly directional, well-controlled, and intense emission of weakly emitting dye generated on chip without the aid of conventional methods opens up a new scheme of random lasing generation mediated by microdroplets.
Highlights
We demonstrate high-quality on chip random lasing of the acceptor dye using a specially designed dynamic linear array of microdroplets with unconventional shapes that do not support the whispering gallery modes
Either decoupling the whispering gallery modes (WGMs) and cavity modes or eliminating the WGMs is preferable to selectively channelize the gain in the system-cavity modes and to investigate the vulnerability of microdroplets towards delivering pure random lasing. An investigation in this aspect is performed in microdiscs using finite difference time domain (FDTD) method and the results are given in Supplement 1
The performance of the linear array is evaluated by comparing the acceptor emission with two other arrays made of microspheres and microtriangular droplets arranged in a zig zag fashion
Summary
We demonstrate high-quality on chip random lasing of the acceptor dye using a specially designed dynamic linear array of microdroplets with unconventional shapes that do not support the whispering gallery modes. For the first time using the microfluidic platform, we are demonstrating the random lasing in the acceptor emission and further reduction in the lasing threshold utilizing the radiative energy transfer (RET) in a dynamic 1D array of microdroplets with intrinsic disorders in the sizes and inter-droplet separation.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
