Black phosphorus/polydimethylsiloxane coated microfiber saturable absorber for ultrashort pulse fiber laser
Fiber lasers capable of generating ultrashort pulses have diverse applications in micromachining, medical science, and telecommunications. Ultrashort pulses generated from fiber lasers can be achieved through passive mode-locking via a saturable absorber (SA). Several black phosphorus (BP) fiber-...
Saved in:
| Main Author: | |
|---|---|
| Format: | Thesis |
| Language: | English |
| Published: |
2021
|
| Subjects: | |
| Online Access: | http://psasir.upm.edu.my/id/eprint/104060/1/FK%202022%2087%20IR.pdf http://psasir.upm.edu.my/id/eprint/104060/ |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Summary: | Fiber lasers capable of generating ultrashort pulses have diverse applications in
micromachining, medical science, and telecommunications. Ultrashort pulses
generated from fiber lasers can be achieved through passive mode-locking via a
saturable absorber (SA). Several black phosphorus (BP) fiber-based saturable
absorbers have been reported with low damage thresholds, however, have poor
repeatability for mass production due to uncontrollable deposition techniques. This
research work focuses on a new technique to generate ultrashort pulses using
optimized adiabatic tapered fiber saturable absorber with different dimensions of
black phosphorus; vary from bulk to quantum dots.
The experimental work was initiated with the optimization of bulk BP polymer
composite based saturable absorbers of different taper profiles in erbium-doped fiber
ring laser cavity. The BP polymer composite was prepared by dispersing BP powders
in tetrahydrofuran solvent then adding in polydimethylsiloxane (PDMS) to form
composite. The sonicated BP was observed in chunky pieces within micrometers,
proven by the scanning electron microscope morphological characterization. The
characteristics of BP, PDMS, and BP/PDMS composite were analyzed through
Raman spectroscopy, field emission scanning electron microscope, and ultravioletvisible-
near infrared absorption spectroscopy methods. A constant amount of BP
polymer composite was deposited within the waist area of tapered fiber through spin
coating method with optimized parameters; 4000 rpm for 6 minutes. The up/down
transition and waist length were optimized with a waist diameter of 10 m was
chosen as the constant parameter. Based on the experimental findings, the optimum
taper profile was 30 mm of up/down transition length and 1 mm of waist length,
which resulted in transmission loss of 3.34 dB, saturation fluence of 21.56 μJ/cm2,
and modulation depth of 3.14%. The fabricated BP/PDMS SA was integrated into a ring cavity erbium-doped fiber laser (EDFL). By adjusting the polarization states of
the circulating light in the cavity, the EDFL produced an optical spectrum with Kelly
sidebands to prove the generation of conventional soliton (CS). The output pulse had
a central wavelength of 1560.18 nm, 3-dB spectral width of 5.92 nm, pulse duration
of 724 fs, repetition rate of 6.53 MHz, and time bandwidth product (TBP) of 0.53
showing the SA capable of generating ultrashort pulses.
Next, black phosphorus layers (BPLs) and black phosphorus quantum dots (BPQDs)
were synthesized from bulk BP through liquid phase exfoliation method. The
findings from high resolution transmission electron microscopy and atomic force
microscopy suggested BPLs were in diameter range from 69 – 362 nm and thickness
range of 42 – 62 nm. Whereas BPQDs displayed a lateral size of 2.92 ± 0.37 nm as
analyzed from the TEM image. Then, BPLs/PMDS and BPQDs/PDMS composite
SA were fabricated following the same procedure as implemented for BP/PDMS
SA. These fabricated SAs were inserted into the same EDFL cavity to study their
pulse performance characteristics. The transmission loss of BPLs/PDMS coated
microfiber was 2.57 dB whereas BPQDs/PDMS composite coated microfiber was
2.12 dB at 1550 nm, respectively. The nonlinear absorption of BPLs/PDMS
composite coated microfiber possesses saturation fluence of 9.22 μJ/cm2,
modulation depth of 3.5%, and two-photon absorption (TPA) of 5.3 x 10-3 cm2/μJ
while the BPQDs/PDMS coated microfiber exhibited saturation fluence of 18.47
μJ/cm2, modulation depth of 2.12%, and TPA coefficient of 9.1 x 10-3 cm2/μJ. The
nonlinear optical absorption response shows that due to different size of BPs, both
SAs showed different TPA characteristics that caused CS to noise-like pulse (NLP)
operation at different pump powers. In the CS operation, BPLs/PDMS composite
SA generated 837 fs which was better in pulse duration compared to 1.11 ps of
BPQDs/PDMS composite SA. Besides that, BPLs-SA had the lowest TBP value
(0.39) among other structures BP-SAs which indicated the pulse was slightly
chirped. However, in the NLP operation, BPQDs-SA showed shortest pulse
generation at 152 fs due to strong TPA characteristic. Overall, the results validate
the reliability of the proposed method to understand the effect of different BP/PDMS
structures on microfiber based SAs for ultrashort pulse generation. |
|---|