Formation of Hybrid Resonators in the Semiconductor Circular Ring
Laser Diode and Its Output Characteristics
Chun Ting Tsen, Ming Chang Shih and Wen Ho Lan
Department of Electrical Engineering, National University of Kaohsiung, Kaohsiung, R.O.C., Taiwan
Keywords: Semiconductor Laser Diode, Circular Ring Resonator, Optical Nonlinearity, Conjugate Reflection.
Abstract: We present the study of the emission characteristics of a semiconductor circular ring laser diode with a Y-
junction output coupler. Instead of laser output from Y-junction coupling terminal, a confined laser beam
output was also observed at non-waveguide region due to optical nonlinearity effect of the multi-quantum
wells active median. It showed that except for the circular ring resonator mode, much complicate modes were
excited from both output terminals. A hybrid resonator formed by conjugated reflection is suggested to explain
the features of output characteristics. In addition, L-I and spectrum characteristics of both output terminals of
these hybrid resonators were analysed to explore the detailed mechanism of these hybrid resonator.
1 INTRODUCTION
Semiconductor laser diode with circular ring
resonator SCRLD had been attracted interest of
research for its long optical path way advantage of
strong side modes rejection and flexibility to be
integrated with other passive components for the
development of more advanced opto-electronic
systems. Recently, it was demonstrated the control of
CW/CCW mode of the SCRLD output by external
injection light that makes it an ideal all light wave
signal processing system. There are also applications
of SCRLD to achieve wavelength filtering and tuning
of the laser output. However, there is not many
studies about the nonlinearity effect of the SCRLD.
We have studied these devices for decades to show
that instead of linear operation laser mechanism, it is
possible to excited more complex optical nonlinear
effects in these SCRLD devices due to strong
nonlinear coefficient of these multi-quantum wells
active material. We had demonstrated the generation
of Soliton waveguide in a SRCLD with a Y-
junction
output coupler and switching control of light beam
coupling. Here we present the study of the formation
of hybrid resonator due to phase conjugate reflection
in this SCRLD device and its output characteristics.
Figure 1: Material structure and dimensions of the
fabricated SRCLD.
2 FABRICATION OF THE SCRLD
DEVICE
As shown in Fig.1, the fabricated SCRLD was
fabricated with a metal organic chemical vaper
deposition (MOCVD) grown GaInP/InGaAlP
multiple-quantum-well(MQW) active structure with
gain spectrum around 650 nm. Figure 2 shows the
device process flow. First, a SiO
2/Au/Cr layer with
the device pattern was achieved by a lift-off process.
Then, structure of the circular ring resonator with
diameter D = 500
m
~1000
m
, depth h= 0.85
m
~0.9
m
, width W=10
m
~25
m
, and the
Y-junction coupling section was etched by
inductively coupled plasma (ICP) etching.
Tsen, C., Shih, M. and Lan, W.
Formation of Hybrid Resonators in the Semiconductor Circular Ring Laser Diode and Its Output Characteristics.
DOI: 10.5220/0010391301310135
In Proceedings of the 9th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS 2021), pages 131-135
ISBN: 978-989-758-492-3
Copyright
c
2021 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
131
Figure 2: Device process flow of the SCRLD.
To eliminate the problem of short contact between
the p-n junction, the depth of the ridge waveguide was
etched about 0.8 μm located at just a distances above
the active layer. Secondly, a passivation layer of the
SiO
2
thin film was deposited using sputtering. Then,
an etch back process was applied to etch out the SiO
2
layer by using BOE wet etching to open the electrode
area. Then, a blank layer of Au (200 nm)/Cr (10 nm)
was deposited on the SiO
2
passivation layer. Then,
the substrate was grinded down to a thickness of 150
μm to minimize the resistivity through the substrate.
Finally, an AuGe/Ni alloy thin film was deposited on
the back side for n-type metal contact and then by
annealing the device at 650 °C for 30 s. The fabricated
device was cleaved by a diamond scriber and tested
on a micro probing station.
3 OUTPUT
CHARCTERIZATIONS
The fabricated SCRLD device was probe-tested on a
micro-probing station for light-current (L-I) and
spectrum measurements. Fig. 2 shows the schematics
of the output characterization system in which an HP
8114A pulse power source was operating at 1 kHz for
the current injection on the test device. By using a
beam splitter cube, the output emission can be
measured by the Si-based photodetector for L-I
characterization, and the Jobin Yvon SPEX 500
spectrometer with resolution of 0.01 nm to analyse
the spectrum of the output emission in the same time.
All devices are connected with a PC by GPIB
interfacing for control and data processing. The
output emission from the tested device was
collimated by an object lens (x10) then through a
beam splitter by which to guide part of the emission
to an IR CCD for visualization of the side view of the
emission from the SCRLD.
Figure 3: Schematics of the output characterization system.
Figure 4: CCD image and profile of the emission from
terminal “S”, which shows high order soliton characteristic.
Instead of strong laser emission observed from the
Y-junction ridge waveguide output coupling terminal
(marked as ”Y”), it was also observed a strong and
confined emission at the opposite direction of
terminal Y on non-waveguide region(marked as “S”).
Fig. 4 shows the far field CCD image and profile of
the emission from terminal “S”, which shows high
order soliton characteristic.
We had previously reported that the confined
emission from the non-waveguide region was the
formation of spatial soliton due to the strong 3
rd
order
nonlinearity of the multiple quantum wells medium.
In principle, the spatial solitons formed as the normal
diffraction of the medium can be exactly balanced by
refractive index changes induced by the electro-optic
nonlinear effect. Since the Kerr effect constant of
most of the optical materials is relatively small, a
power density of light on the order of MW/cm
2
is
required to form Kerr effect solitons. It was reported
that spatial solitons could be excited by electric-field-
induced refraction index changes in photorefractive
or photovoltaic media. In the case of photorefractive
spatial solitons, the distribution of the field intensity
of a light beam modulates the index of refraction of
the medium via the photorefractive effect, which
compensates for the natural diffraction and achieves
the confinement of the beam profile along the
propagation direction. Photorefractive spatial solitons
can be formed at a relatively lower power of around
100mW that makes them attractive for applications in
PHOTOPTICS 2021 - 9th International Conference on Photonics, Optics and Laser Technology
132
integrated optoelectronic devices such as all-optical
light wave control of guiding, switching, and signal
modulation.
Figure 5: L-I measurement of the SRCLD with diameter D=
750 um, the length of Y-junction coupling section L
1
=1250
um, and the length of non-waveguide section L
2
=600 um.
Fig. 5 shows the L-I measurements at both terminal
“Y” and terminal “S” of a SCRLD with D=750
m
,
W= 20
m
, h= 0.9
m
, length of Y-junction
coupling section L
1
=1250
m
, and length of soliton
resonator L
2
=600
m
. Threshold currents of both
outputs terminal are very close at 0.06 A( ~60 A/cm
2
).
Fig. 7a shows the emission spectrum from Y-junction
terminal “Y” with various injection bias. The
emission peak at 652.80 nm is referred to the CW and
CCW propagation mode in the circular ring resonator
and being coupled out through the Y-junction coupler.
As the injection current increase; from 0.1 A to 0.14
A, new spectral peaks located at 650.0 nm and 656.0
nm starting to take off. Peaks position of λ
1
=652.8 nm,
λ
2
=650.0 nm, and λ
3
=656.0 nm are very close to the
relationship of four waves mixing as
321
112
due to 3
rd
order optical nonlinearity excited by
CW/CCW propagation modes in the circular ring
resonator. It is worth to note that λ
1
=652.8 nm might
referred as the zero dispersion point for this four wave
mixing; FWMX system. Fig. 7b shows the emission
spectrum at soliton terminal “S” that seems close to
the spectrum of terminal “Y” only with a little
deviations of the position between these two
spectrums. In addition to the spectrum measurements,
a polarizer was place at the entrance of the Jobin
Yvon SPEX 500 spectrometer to examine the
polarization of the emission. The result showed that
the emissions from both hybrid resonators were linear
polarized as expected. Fig. 6 shows the measurement
of the polarization scan of the emission from soliton
output terminal.
Figure 6: Polarization scan of the emission from the soliton
output terminal.
Figure 7a: Emission spectrum from the Y-junction
resonator.
Figure 7b: Emission spectrum from the soliton resonator.
Formation of Hybrid Resonators in the Semiconductor Circular Ring Laser Diode and Its Output Characteristics
133
Figure 8: Schematic diagram that described the formation
of the hybrid resonator.
Figure 9a: Emission spectrum at high current injection from
the Y-junction resonator with resonator length L
1
=1250 um.
Figure 9b: Emission spectrum at high current injection from
the soliton resonator of a length L
2
=600 um.
At high injection up to 0.16 A, it is shown that
discrete peaks λ
2
=650.0 nm and λ
3
=656.0 are
diminishing by taking off a broaden multi-modes
spectrum features located at 654 nm.
A model of hybrid resonator formation is
described in Fig. 8. In the MWQ material with high
3
rd
order nonlinearity coefficient, phase conjugate
reflection can be excited at the intersection region of
the Y-junction coupling section and the circular ring
resonator by counter propagating modes of E
1
(CW)
and E
2
(CCW) in the ring resonator. Light reflected
from the cleaved mirror at the end of the ridge
waveguide Y-junction coupling terminal will be
amplified by phase conjugated reflection and form a
linear resonator. By the same way, another linear
resonator located at the opposite direction of the Y-
junction coupling section can also be formed due to
the confinement of the spatial soliton and
amplification by conjugated reflection. The light
amplification factor is increasing with the intensity of
the ring resonator. In fact, lasing condition of this case
is required by the longitudinal modes of the linear
resonator and the FWMX phase matching condition.
It is explained that spectrum peaks of λ
2
=650.0
nm and λ
3
=656.0 are dominating in the emission of
the hybrid resonator. As the injection current keep
increasing to the oscillating point of the conjugate
reflection, the amplification factor of the resonator
drops, as a result the loss of the linear resonator
increase and the emission become broaden. In Fig.5,
a turning point at 0.16 A of the L-I curve is referred
to the reaching of the oscillating point of the
conjugate reflection.
In principle, the circular ring resonator function as
the pumping source for the generation of optical
nonlinearity effect and the outputs modes of the
hybrid resonator are controlled by the optical property
of itself. Fig. 9a shows the detailed spectrum of the
longitudinal modes of the Y-junction resonator of a
length L
1
=1250
m
at current injection above 0.16A.
The modes spacing of 0.05 nm is close to the
calculated value using parameter of index of
reflection n=3.6 of the laser medium and the resonator
length of L
1
=1250
m
. Fig.9b shows the emission
spectrum of the soliton resonator of a length L
2
=600
m
. It shows that the modes spacing of 0.1 nm
which is also very close to calculated value using the
resonator length of L
2
=600
m
.
4 CONCLUSIONS
We have demonstrated that the formation of hybrid
resonators of the SCRLD and its output
characteristics. The conjugated reflection excited by
the strong emission in the circular ring resonator play
an important role to the formation of hybrid
resonators. Since the FWMX is coherent light
interaction in nature thus suggested the laser emission
from the hybrid resonator is coherent, and it is
essential for the development of more advanced opto-
electronic devices applying coherent signal
PHOTOPTICS 2021 - 9th International Conference on Photonics, Optics and Laser Technology
134
processing. Further experimental results to explore
the nonlinearity effect in the SCRLD will be
presented in the near future.
ACKNOWLEDGEMENTS
We would like to thank to Union Optronics
Corporation for their help in device processing and
Ms. W. C. Lin and colleagues for preparing the
experimental data and manuscript. We would also
like to thank the Ministry of Sciences and Technology
in Taiwan for funding this research under the project
number of 107-2221-E-390-014.
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