Title :
Self-Assembled Graphene Membrane as an Ultrafast Mode-Locker in an Erbium Fiber Laser
Author :
Gui, Lili ; Zhang, Wei ; Li, Xiao ; Xiao, Xiaosheng ; Zhu, Hongwei ; Wang, Kunlin ; Wu, Dehai ; Yang, Changxi
Author_Institution :
Dept. of Precision Instrum., Tsinghua Univ., Beijing, China
Abstract :
A self-assembled graphene membrane produced at the liquid/air interface of reduced graphene oxide aqueous suspension is demonstrated as an excellent mode-locker in an erbium-doped soliton fiber laser. Formation of the self-assembled membrane is attributed to hydrophobic nature of graphene and considerable capillary force. Experiments showed that such graphene saturable absorbers with insertion loss less than 6 dB worked well in the laser cavity setup, verifying that the self-assembly method is reliable and practical. Moreover, the method is quite facile, cost-effective, and potentially suitable for large-scale production of graphene mode-lockers.
Keywords :
erbium; fibre lasers; graphene; high-speed optical techniques; hydrophobicity; laser cavity resonators; laser mode locking; membranes; optical saturable absorption; ring lasers; self-assembly; C; capillary force; erbium-doped soliton fiber laser; graphene oxide aqueous suspension; graphene saturable absorbers; hydrophobicity; self-assembled graphene membrane; self-assembly method; ultrafast mode-locker; Cavity resonators; Erbium-doped fiber lasers; Laser mode locking; Optical fiber devices; Optical fiber dispersion; Optical fibers; Suspensions; Graphene saturable absorber; mode-locked fiber laser; self-assembly;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2011.2169660
