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Efficient Fluorescence Utilization and Photon Density of States‐Driven Design of Liquid Crystal Lasers.

Authors :
Qu, Guangyin
Hu, Lei
Li, Siqi
Kuai, Yan
Cao, Zhigang
Liu, Yu
Xie, Kang
Yu, Benli
Hu, Zhijia
Source :
Laser & Photonics Reviews; Jun2024, Vol. 18 Issue 6, p1-9, 9p
Publication Year :
2024

Abstract

Liquid‐crystal random lasers (LCRLs) represent a burgeoning field in soft‐matter photonics, holding promise for ushering in an era of ultrathin, versatile laser sources. Such lasers encompass a multitude of remarkable features, including wide‐band tunability, large coherence area and, in some cases, multidirectional emission. In this paper, an LCRL is developed by doping a laser dye, pyrromethene 597 (PM597), into cholesteric LC, but achieving a wide‐range wavelength‐controllable (560–720 nm) bandgap lasing through voltage control. Bandgap lasing intriguingly occurs in media with extremely low dye gain, which is mainly contributed by the extremely high photon density of states (DOS) at the edge of the LC bandgap. In addition, the utilization rate of the fluorescence spectrum (550–750 nm) of laser dye PM597 is as high as 80%. The multivariate linear regression model is used to characterize the inherent relationship between the lasing intensity emitted by LC and the photon DOS, fluorescence quantum yield, and internal scattering under specific pumping energy. This model shows the potential to predict the critical conditions of laser emission accurately and provides the capability to design and fabricate large‐scale multifunctional responsive photonic crystals using a simple fabrication procedure. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
18638880
Volume :
18
Issue :
6
Database :
Complementary Index
Journal :
Laser & Photonics Reviews
Publication Type :
Academic Journal
Accession number :
177773343
Full Text :
https://doi.org/10.1002/lpor.202301122