Title :
Graphene Q-Switched Mode-Locked and Q-Switched Ion-Exchanged Waveguide Lasers
Author :
Choudhary, Amol ; Dhingra, Shonali ; D´Urso, Brian ; Kannan, Pradeesh ; Shepherd, David P.
Author_Institution :
Optoelectron. Res. Centre, Univ. of Southampton, Southampton, UK
Abstract :
In this letter, we present the use of monolayer graphene saturable absorbers to produce Q-switched and Q-switched mode-locked operation of Yb and Yb:Er-doped phosphate glass waveguide lasers, respectively. For the 1535-nm-wavelength Yb:Er laser, the Q-switched pulses have repetition rates up to 526 kHz and contain mode-locked pulses at a repetition frequency of 6.8 GHz. The measured 0.44-nm bandwidth should allow pulses as short as ~6 ps to be generated. Maximum average output powers of 27 mW are obtained at a slope efficiency of 5% in this mode of operation. For the 1057-nm-wavelength Yb laser, Q-switched pulses are obtained with a repetition rate of up to 833 kHz and a maximum average output power of 21 mW. The pulse duration is found to decrease from 292 to 140 ns and the pulse energy increase from 17 to 27 nJ as the incident pump power increases from 220 to 652 mW.
Keywords :
Q-switching; erbium; graphene; laser beams; laser mode locking; monolayers; optical glass; optical pulse generation; optical pumping; optical saturable absorption; phosphate glasses; solid lasers; waveguide lasers; ytterbium; C; P2O5:Yb; P2O5:Yb,Er; Q-switched pulses; Yb:Er-doped phosphate glass waveguide lasers; efficiency 5 percent; frequency 6.8 GHz; graphene Q-switched ion-exchanged waveguide lasers; graphene Q-switched mode-locked waveguide lasers; incident pump power; mode-locked pulses; monolayer graphene saturable absorbers; output powers; power 21 mW; power 27 mW; pulse duration; pulse energy; pulse generation; repetition frequency; repetition rate; slope efficiency; wavelength 1057 nm; wavelength 1535 nm; Glass; Graphene; Laser mode locking; Measurement by laser beam; Optical waveguides; Semiconductor lasers; Waveguide lasers; Erbium; femtosecond pulse; high repetition rate; optical pulses; optical waveguides; solid-statelaser; ytterbium;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2015.2389631
