MMI Fiber Optic Refractometer with Universal pH Indicator
Coating
Adolfo Rodríguez-Rodríguez
1
, René Domínguez-Cruz
2
, Daniel May-Arrioja
3
,
Ignacio Matías-Maestro
4
, Carlos Ruíz-Zamarreño
4
and Francisco Arregui
4
1
Department of Computer Systems Engineering, Autonomous University of Tamaulipas, Apdo. Postal 1460, Col. Arcoiris,
Reynosa, Tamaulipas, Mexico
2
Electrical and Electronics Department, Autonomous University of Tamaulipas, Apdo. Postal 1460, Col. Arcoiris, Reynosa,
Tamaulipas, Mexico
3
Centro de Investigaciones en Óptica, Unidad Aguascalientes, Prol. Constitución 607, Fracc. Reserva Loma Bonita,
Aguascalientes, Ags, Mexico
4
Departamento de Ingeniería Eléctrica y Electrónica, Universidad Pública de Navarra, Edif. Los Tejos,
Campus Arrosadía-31006, Pamplona, Spain
Keywords: Fiber Optic, Refractometer, Multimodal Effect, Universal pH Indicator.
Abstract: In this paper we show the preliminary results about fabrication of an optical fiber refractometer based on
multimode interference effects (MMI) provided with Universal pH Indicator coating. The layer, deposited
by coating dip-coating technique, allows increase the refractometer sensitivity which is around 344.5054
nm/RIU in a range of 1.333 to 1.4223. Highly repetitive and reversible refractometer have been achieved
using a simple fabrication process. The device shown offers the possibility to be used as instrument to
identify substances included aggressive liquids as gasoline.
1 INTRODUCTION
The refractometer is an interesting and useful tool to
analize the compounds and concentrations. This is
due to many applications as in biology, medical
science, environment control and process
engineering area. In this sense, optical fiber based in
refraction index (RI) sensors have been studied
broadly due to the advantages they offer such as
immunity to electromagnetic interference, compact
size, remote operation, high sensitivity and the
wavelength signals multiplexing. Some techniques
to implement RI sensing incorporate a fiber Bragg
gratings FBG (Han et al, 2010), long period gratings
LPG (Allsop et al, 2002), macro-bend single mode
fiber (Wang et al, 2009), surface plasmon resonance
(Liang et al, 2010), a Fabry-Perot interferometer
(Frazao et al 2009), or multi-D-shaped optical fiber
(Chen et al, 2010). However, an alternative,
attractive, low cost and simple technique for RI
measurements is based in multimodal interference
effects (MMI). MMI effect in optical fiber is
obtained by splicing a segment of Multimode Fiber
(MMF) between two segments of single mode Fiber
(SMF) as is showed in Figure 1. The MMI effect
relies on the fact that when the light field coming
from the input SMF enters the MMF, will excite
several modes, propagating along the MMF section,
thus causing interference between them. This means
that the optical power coupled to the output SMF
will depend on the amplitudes and relative phases of
the various modes at the exit end of the MMF. Also,
the MMI fiber structure can act as a bandpass filter
or edge filter depending on the length of the MMF
used. Thus, the operating principle of sensors based
on MMI structures relies in the interference between
excited modes that are propagating in MMF section,
which can be influenced by external perturbation
(Wang and Farell, 2006). Additionally, the MMI
devices has been proposed as sensors for micro-
displacement measurements (Antonio-Lopez et al,
2013), level sensor (Antonio-Lopez et al, 2011) and
temperature sensor (Ruiz-Perez et al, 2012).
Rodríguez-Rodríguez, A., Domínguez-Cruz, R., May-Arrioja, D., Matías-Maestro, I., Ruiz-Zamarreño, C. and Arregui, F.
MMI Fiber Optic Refractometer with Universal pH Indicator Coating.
DOI: 10.5220/0005821702730276
In Proceedings of the 4th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS 2016), pages 275-278
ISBN: 978-989-758-174-8
Copyright
c
2016 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
275
Figure 1: Structure of MMI element built in optical fiber.
(SMF, single mode fiber; MMF, multimode fiber).
In other hands, a universal indicator is
collectively a mixture of indicators which show a
colour change in a solution, which interprets how the
acidity or alkalinity of solutions is. Typically, a
universal indicator can be in paper form or present in
a form of a solution (Walker, 2007). Novel uses for
Universal pH Indicator have been proposed in
optical fiber sensors, such as ammonia detection
(Rodríguez et al, 2014) and in medicine field for
physiological processes in the patient’s body (Zajíc
et al, 2015). In this work we show a simple MMI
structure for RI measurements using No-core
Multimode fiber spliced between two Single Mode
fibers covered with a Universal pH Indicator coating
to increase the sensitivity. The MMI sensor is able to
detect different liquids such as water, ethanol
anhydrous and other liquid substances more
aggressive as gasoline.
2 EXPERIMENTAL SET-UP
2.1 MMI Refractometer Fabrication
To fabricate the refractometer based on the MMI
effect shown in this paper, we used two SMF
segments (with diameter of 8.2 µm for the core and
125 µm for coating) and No-core Multimode fiber
segment, NC-MMF (with diameter of 125 µm). For
a 58.13 mm segment of NC-MMF, their polymer
jacket was removed using acetone and it is spliced
between two SMF segments using a FSM Fujikura®
60S splicer. Lately, the NC-MMF section was
coated with the pH sensitive solution using a
standard dip-coating technique by deposition system
from Nadetech, Inc.® (Pamplona, Spain). The NC-
MMF fiber was inserted and pulled out of the
solution at a rate of 150 mm/min while the
temperature was maintained at 100 °C during the
whole process. The coated MMF element sensor was
kept at room temperature during 20 min, and then
placed into an oven for thermally curing at 85 °C for
15 min. To avoid losses for bending, we fixed the
MMI element on the surface of a chamber and we
perform all our measurement at room temperature.
To prepare pH sensitive solution, we use
Universal pH Indicator provided by the company
(PANREAC), which is made of a mixture of various
indicators such as methyl red (40 mg), p-
dimethylaminoazobenzene (60 mg), bromothymol
blue (80 mg), thymol blue (100 mg) and
phenolphthalein (20 mg) (Indicator Universal de pH,
2013). In order to immobilize the indicator on the
surface of the MMF fiber, the polymer is
incorporated into a thermoplastic host that allow
simple coating of the optical fiber. The pH sensitive
solution was prepared by mixing 120 mL of ethanol,
120 mL of pH universal indicator, and 4.32 g of
thermoplastic polyurethane (TPU), Tecoflex®
provided by the company Thermedics (Newton, NJ,
USA).
2.2 Experimental Array
Once upon fabricated the MMI refractometer and
fixed into a chamber, the ends of the SMF segments
are fused to single mode optical fiber provided with
FC/PC connectors. One of these connectors is
plugged to a Super-luminescent laser diode source
(SLD). The optical signal is propagating into the
MMI structure and is detected by an Optical
Spectrum Analyzer (OSA) ANRITSU MS9780. The
full experimental system is shown in Figure 2.
Figure 2: Experimental set-up.
To determine the operating parameters of the
MMI structure, we used the self-image distance L,
given as (Wang and Farell, 2006):
L= p
n
MMF
2
D
MMF
2
λ
o
; p=0, 1, 2, 3…
(1)
where D
MMF
= 125 µm and n
MMF
= 1.444 are the
diameter and refraction index of the NC-MMF
respectively, λ
o
is the wavelength in free space and p
is the number of the input field image that replicates
at the end of the MMF segment. However, due to the
nature of the MMI effect, the true images of the
input field are given at every fourth image (p=4).
PHOTOPTICS 2016 - 4th International Conference on Photonics, Optics and Laser Technology
276
The images formed at other positions are known as
pseudo-images, and although they resemble the
input field they exhibit higher losses. Thus, all our
experiments were operated at the fourth image of
MMI refractometer. To obtain tuning in 1560 nm in
air, the length of the NC-MMF must be L
π
=58.13
mm. A good approximation of the Equation (1) was
experimentally confirmed by the response of the
MMI structure shown in Figure 3.
Figure 3: Spectral response in air of MMI refractometer
without coating.
2.3 Results and Discussion
The MMI refractometer was initially characterized
without Indicator pH Universal coating with some
liquids such as water (n= 1.333), anhydrous ethanol
(n~1.3611), and commercial gasoline with 98
octanes and gasoline with 95 octanes (n ~ 1.4223).
The refractometer response to the different refractive
indexes is shown in Figure 4.
Figure 4: Spectral response of MMI refractometer without
coating for several liquid substances surrounding.
When we cover the NC-MMF segment with
water, anhydrous ethanol or gasoline, the condition
of self-image in the structure of MMI is modify and
we estimate a sensitivity around 290.1098 nm/RIU
(refractive index units).
The variation in humidity and temperature do not
significantly affect the behavior of MMI
refractometer when the measurements is performed.
Additionally, the recovery time of the device is less
than 15 seconds after a washing with acetone.
Due to the sensitivity of the MMI sensor is
directly related to the effective diameter (i.e. the
diameter of the NC-MMF and the surrounding
environment), we decided to fix on the NC- MMF a
coat of Universal pH Indicator coating thickness as
we explain in Section 2.1. The response of this new
refractometer shown in Figure 5. In this case, we can
estimate a sensitivity around 344.5054 nm/RIU.
Figure 5: Spectral response of MMI refractometer
provided with a Universal pH Indicator coating for several
liquid substances surrounding.
In Figure 6 we shows the shift of wavelength
peak for both MMI refractometers fabricated. In this
curve, we observe the increase in the sensitivity
when NC-MMF is provide with a Universal pH
Indicator coating. As consequence, this MMI device
offers a better resolution for the substances used.
Figure 6: Comparison of the wavelength shifts for
different MMI refractometers designed.
MMI Fiber Optic Refractometer with Universal pH Indicator Coating
277
As we explained before, a MMI structure is
fabricated by splicing a segment of MMF between
two SMF segments. In our device the MMI structure
is able to see the liquid surrounding the fiber
because the MMF does not have a cladding. A
simple way to enhance the sensitivity of the MMI
structure is to cover the MMF with a high RI thin
film. One aspect to consider is the control of the
coating thickness. If the film is too thick, it will start
guiding and all light from the MMF will be coupled
into the high RI film. When the MMI device with
high RI film is covered with a liquid, the effective
diameter of the fundamental mode is increased as
compared to a MMI structure without film under the
presence of the same liquid. As shown in Figure 6,
the MMI structure without film exhibits the typical
wavelength shift for the RI liquids (blue line).
Nevertheless, when the MMI structure is provided
with Universal Indicator coating, the MMI device
exhibit a larger wavelength shift and hence a higher
sensitivity (red line).
3 CONCLUSIONS
This paper we shown a fiber optic refractometer
based on the effect of multimodal interference
(MMI) provided with a Universal pH Indicator
coating on NC-MMF fiber and it was tested to detect
different liquids. The MMI device has a high
reproducibility and reversibility, no significant
interference against temperature or humidity.
The fabricated devices provide a simple and
inexpensive solution (based in a segment of NC-
MMF with specified length spliced between two
segments of SMF). The sensitivity of the structure is
increased when a layer of Universal pH indicator is
deposited on NC-MMF, which is 344.5054 nm/RIU.
The device can be a tool in the detection or
identification of substances included aggressive
liquids as gasoline, where the measured variable
depends of refractive index.
ACKNOWLEDGEMENTS
A.R.R. and R.D.C. thank the UAT for the support to
achieve this work. This paper was also supported by
the Spanish Economy and Competitivity Ministry-
TEC2013-43679-R.
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