ABSTRACT
We demonstrate a spatially and electrically tunable random lasing based on polymer-stabilized blue phase liquid crystal (PS-BPLC)-wedged cell. The spatially tunable random lasers can be obtained from the laser dye-doped PS-BPLC-wedged cell through changing the pump positions, where the emission wavelength of the random laser can be tuned due to the thickness gradient of the wedged cell, which affects the scattering mean free path. Additionally, applying different electric fields can also tune the laser emission wavelength. The changing of refractive index due to the Kerr effect leads to a change in the scattering mean free path, resulting in shift of lasing wavelength. This PS-BPLC-wedged cell device has a great potential in applications of speckle-free imaging, document coding, biomedicine and other photonic devices.
![](/cms/asset/1a7dd553-ec57-4acb-b379-fce43c55f47c/tlct_a_1673842_uf0001_c.jpg)
POM images of gradient-pitched PS-BPLC-wedged cell at different positions of (a) x=0 mm; (b) x=1 mm; (c) x=2 mm; (d) x=3 mm; (e) x=4 mm; (f) x=5 mm; (g) x=6 mm; (h) x=7 mm; (i) x=8 mm. The scale bar is 50 μm.
Disclosure statement
No potential conflict of interest was reported by the authors.