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This work is licensed under a Creative Commons Attribution 4.0 International License. 
 

 

   

 

 

 

 

 
 

 

 

 
 

 

 

Abstract 

The Optical Fiber sensor based on the Surface Plasmon Resonance (SPR) technology has 

been a successful performance sensing and presents high sensitivity. This thesis investigates the 

performance of several structure of SPR sensor in field of refractive index and chemical 

applications. A structure of Multi-Mode Fiber- Single Mode Fiber- Multi Mode Fiber (MMF-

SMF-MMF) had been designed and manufactured. The outer diameter of the SMF sensing region) 

had been reduced to (65, 45, and 25) µm. This is achieved using the chemical etching method. 

Then this sensitive area coated with gold layer using Magnetron Sputtering plasma System. The 

thickness of the gold layer is (40 nm).In most of the previous research in this field of the line of 

research: the surface Plasmon resonance sensor experiment is conducted using light sources with 

a wide range of wavelengths. To improve the accuracy of analysis (resolution), helium-neon laser 

was used as a light source when determining the Plasmon resonance wavelength as a function of 

the index of refraction of chemical solutions. The sensitivity for samples of salt solutions was 140 

and 142 (nm/RIU) for the two dips of the spectrum and the sensitivity for samples of glucose 

solutions was 38 and 42 (nm/RIU) for the two dips of the spectrum. 

Keywords: Chemical optical fiber sensor, Chemical etching, single mode optical fiber, Laser, 

Surface Plasmon Resonance. 

1. Introduction 

The first studies in optical fiber sensors that adopted surface Plasmon resonance were 

conducted in 1993 by Jorgenson and Yee[1].Fiber-optic sensors have many applications in 

environmental, communication technology, biological, chemical, and medical fields. This is due 

to the fact that these sensors are small in size and have high sensitivity for minimal changes in 

parameters of the samples to be sensed [1,2].The surface Plasmon resonance (SPR) sensor relies 

on the fact that the surface of Plasmon is stimulated by electromagnetic waves and influenced by 

doi.org/10.30526/36.2.3002 

Article history: Received 6 October 2022, Accepted 24 October 2022, Published in April 2023. 

 

 

 

Ibn Al-Haitham Journal for Pure and Applied Sciences 

Journal homepage: jih.uobaghdad.edu.iq 

 

Employment the Laser to Fabricate the Surface Plasmon Resonance Sensor 

 

Tammara Jamal Mossa 

Department of physics, College of science for 

women, University of Baghdad, Baghdad, Iraq. 

tamara.jamal1204a@csw.uobaghdad.edu.iq 

 

 

 

Haider Y. Hammod 

Department of physics, College of science for 

women, University of Baghdad, Baghdad, Iraq. 

haider.y@csw.uobaghdad.edu.iq 

 

 

https://creativecommons.org/licenses/by/4.0/
mailto:tamara.jamal1204a@csw.uobaghdad.edu.iq
mailto:haider.y@csw.uobaghdad.edu.iq


IHJPAS. 36(2)2023 

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changes in the refractive index of material around the surface of the metal, which is deposited very 

thin on the optical fiber core, as an alternative to the lower refractive index of the optical fiber core 

material [3,4,5].This method of optical detection relies on the principle of the interaction between 

the free electron waves present in metals and the electromagnetic waves falling on them. 

Resonance occurs when the wavelength of the incident light is equal to the wavelength of the 

oscillation of free electrons. As a result of this reaction, the intensity of the wave reflected off the 

medium is due to a large portion of its energy being transferred to the deposition layer of the metal 

[6,7].The most important optical elements that can be used to study these processes are high 

refractive indices prism, optical gratings, and optical fibers that have become widely used recently. 

These sensors were widely used in science, education, and industry due to the importance of non-

destructive samples, its high sensitivity, and acceptable selectivity. When light is absorbed, the 

surface Plasmon resonance sensor detects resonant electron oscillations across both the metal 

surface and a dielectric substrate. The advantages of optical fiber sensors are that they are highly 

sensitive, light in weight, and in small diameter, its exposure to electromagnetic waves is minim 

[8].  

 This sensor is usually made of silica fiber and its mode (SMF) and multimode (MMF) types, and 

because of its cost, it has been replaced by a plastic fiber, which is highly flexible and easy to 

design. In order to create a strong optical fiber surface Plasmon resonance, it is crucial to improve 

its efficiency factors including such sensitivity, signal to noise ratio, etc. (SPR). These output 

properties are mostly influenced by the sensor's geometric layout and a few physical factors, such 

as the existence of surface treatments and the materials' dielectric continuity. It is claimed that the 

ideal geometry and the key variables that govern how the sensor interacts are the source of the 

issue [3]. 

2. Theoretical concepts 

There are a number of parameters commonly studied to measure the performance of such 

sensors, which use optical fibers as a key component in their construction, by comparing the 

properties of the input light to those of the output light. The first of these variables is sensitivity, 

which is defined as the ratio between the change in resonance wavelength values and the 

corresponding change in the index of refraction of ambient matter and contact with metal, 

according to the following equation [9].  

        Sn =
δλres

δns
     ------ (1) 

Where (Sn)is the sensitivity and (λres) is the resonance wavelength and (ns) is the equivalent 
change in the index of refraction.  

The most important variable that we've been looking at is how important it is to use a laser instead 

of a light. This variable is the resolution of the sensor and can be mathematically defined as the 

least change in the index of refraction of a material that can be detected by the sensor used. It is 

given the following relationship [9]. 

𝑅 =  
δns

𝛿𝜆𝑟𝑒𝑠
 𝛿𝜆𝐷𝑅 --------- (2) 

Where (𝑅)is the resolution (𝛿𝜆𝐷𝑅) is the spectral resolution of the spectrometer 



IHJPAS. 36(2)2023 

173 
 

Fig [1] the photographic image of SPR sensor based on macro bending optical fibers where [1] 

He: Ne laser Source, [2] SPR macro bending Sensor, [3] different solutions, [4] OSA with Pc. 

they are arranged. 

3. Preparing sensor and setup:  

The main structure of this sensor consists of three types of optical fiber: the central fiber, 

which is the sensing region of the single mode (SMF) type, is associated at the end with another 

optical fiber, which is multimode (MMF), to control the entry and exit of the light signal. SMF 

fiber with a standard core/cladding diameter (10/125) µm and a suitable length of 3cm.The fiber 

was stripped and thoroughly cleaned. Then the stripped area was immersed in dilute hydrofluoric 

acid at 40% concentration for 180 seconds to obtain a diameter of 65µm. The fiber is then cleaned 

again to deactivate the acid and completely stop the chemical reaction by placing the fiber in 

distilled water for several minutes. The diameter of the outer fiber has been measured using a 

(Nikon Eclipse ME600) type of optical microscope with a magnification to (100X). To obtain a 

layer of surface Plasmon metal, a previous stripped fiber coating with gold Nano particles is done. 

The most common method used is sputtering to produce a thin film of this material. This method 

is known as physical vapor deposition (PVD) and occurs in a vacuum of air, where the Nano 

materials are deposited on the surface of the samples by extracting atoms from the material to be 

deposited and concentrating them on the samples. As for the gold-layer thickness obtained by this 

method, it was 40 nm by controlling the process of spraying the thickness of the gold layer could 

be controlled in this work 15 min was the required time to get this thickness. After this stage was 

completed, this part of the sensor at both ends was linked to an optical fiber of a (MMFs) type by 

using an optical fiber splicer machine Fujikura (FSM-60S Japan). 

With regard to the preparation of the test samples, which are represented by solutions of different 

concentrations and correspond to different refractive indices. They were made of both salt and 

sugar. Concentrations ranged from (0.05 - 0.45) moll/L and these refractive indices were measured 

using a device Refractometer ((BOECO Digital ABBE Refractometer). For the setup of the 

experiment, one end of the sensor was delivered to a 632.8 nm Helium-Neon laser source, and the 

other end was delivered to an optical spectrum analyzer (OSA) (Ocean Optics USB- 2000) with 

range (200-1100) nm. The reaction area of the sensor, SMF, is submerged in saline and sugar 

solutions, alternately to show the effect of changing concentrations on the output signal. The 

reflection spectrum is directly measured and analyzed for each reflection state of the transmitted 

signal. Figures (1, 2) shows the photographic image at the set up. 

 

 

 

 

 

 

 

 

 

 

 

1 

2 

4 3 



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174 
 

          

 

 

 

 

 

 

 

 

 

 

4. Results and discussion: 

At this stage, some changes have been made to experiments that are typically conducted in 

this field, using a laser source instead of a conventional light source and increasing the intensity 

losses of the light entering the sensor by bending the optical fiber at the sensing zone to improve 

its performance. 

4.1 influence of the fiber bending: 

To increase the intensity of the light that's involved in the interaction with the surface wave 

of the metal, the bending of the optical fiber increases the intensity losses of the light that's passing 

through the optical fiber. When we draw the relationship between intensity and wavelength, for 

both cases, with and without bending in straight optical fiber and the micro bending fiber, we see 

that there are multiple dips that represent the intentional losses in intensity that will improve the 

performance of the sensor. Figure (3) shows that. 

 

 

 

 

 

 

 

 

 

Fig [3] the influence of micro bending in transmitting light 

Fig [2] a schematic diagram of the main experimental components and how they are arranged. 

 



IHJPAS. 36(2)2023 

175 
 

4.2 Measure the resonance wavelength 

        For NaCl solutions: To test the performance of the sensor, saline solutions of different 

concentrations (corresponding to different refractive indices) were used. When observing the 

optical spectrum analyzer, the relationship between laser wavelength and the reflectivity of the 

metal surface was drawn. In the presence of the solutions, the wavelengths of the plasma resonance 

and for two dips were determined. The sensitivity of the sensor was calculated by using the 

equation (1) also the resolution of the sensor was calculated using equation (2) for two dips. From 

Tables (1, 2) and Figure (4) we can see that there is an improvement in this parameters.  

                          

       

 

 

 

 

 

 

 

 

 

 

 

 

 

Table (1) illustrate the values of resonance wavelengths and  calculated sensor parameters 

RI of NaCl solution 

(RIU) 

Resonance Wavelength 

(nm) for dip 1 

Resonance Wavelength (nm) for dip2 

1.3436 628.467 635.467 

1.344 628.485 635.495 

1.3445 628.565 635.572 

1.3451 628.602 635.612 

1.3456 628.681 635.68 

1.3461 628.758 635.768 

1.3468 628.823 635.833 

1.347 628.903 635.901 

1.3476 628.983 635.993 
1.3481 629.095 636.095 

Table (2) the sensitivities and spectral resolution of macro bending SPR- optical fiber immersed into salt solution 

Resonance dip 
Sensitivity 

(nm/RIU) 

Spectral Resolution 

(RIU) 

Dip 1 140 7.14 x10-4 

Dip 2 142 7x10-4 



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176 
 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

 

 

 

 

 

 

4.2.1 Resonance wavelength as a function of RI 

          Based on the previously calculated values listed in two Tables (1, 2), the relationship 

between resonance wavelengths are drawn as a function of the different refractive coefficients of 

saline for both dips. When looking at these relationships, a direct relationship between the two 

variables was found, meaning that increasing the refractive index of the saline shifted the resonant 

wavelength towards the long values (red shift). Figures (5) show these relations.  

 

 

627.5 628.0 628.5 629.0 629.5 630.0
-2500

-2000

-1500

-1000

-500

0

500

1000

(b)

 

 

dip 1

R
e
fl

e
c
ta

n
c
e
 (

R
.U

.)

Wavelength (nm)

628 630 632 634 636 638
-3000

-2500

-2000

-1500

-1000

-500

0

500

1000

1500

(a)

dip 2

dip 1

 

 

R
e

fl
e

c
ta

n
c

e
 (

R
.U

.)

Wavelength (nm)

 RI=1.3436 RIU

 RI=1.344  RIU

 RI=1.3445 RIU

 RI=1.3451 RIU

 RI=1.3456 RIU

 RI=1.3461 RIU

 RI=1.3468 RIU

 RI=1.347  RIU

 RI=1.3476 RIU

 RI=1.3481 RIU

Fig [4] the relationships between wave length and reflectance recorded by OSA in RPS 

for  NaCl at two dips (a) the all spectrum, (b) zoom spectrum of dip1, and (c) zoom 

spectrum of dip2. 

635.0 635.2 635.4 635.6 635.8 636.0 636.2 636.4 636.6 636.8
-3000

-2500

-2000

-1500

-1000

-500

0

500

1000

dip 2

(c)

 

 

R
e
fl

e
c
ta

n
c
e
 (

R
.U

.)

Wavelength (nm)



IHJPAS. 36(2)2023 

177 
 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

4.3 Measure the resonance wavelength 

          For C12H22O11 solutions: In this section of research, the sensor was tested using another 

chemical compound, and all previous brine steps were repeated. As a first step, the compound was 

prepared in close concentrations, corresponding to different refractive indices with very little 

change in values, distinguishing this sensor from the others that detect the smallest changes in the 

samples being tested. This gives different values for the resonance wavelengths for each 

corresponding index of refraction. After drawing the relationships between the wavelength of light 

incident at the reaction area of the sensor and its reflectance from the contact layer between the 

metal and the chemical solution, the Figure (6) were obtained. Using the equations (1, 2) and with 

the help of the figures drawn, the sensitivity and resolution of the sensor can be calculated, as 

shown in the Tables (3, 4). 

 

 

 

 

 

Table (3) the values of resonance wavelengths and  calculated sensor parameters 

RI of C12H22O11 solution 

(RIU) 

Resonance Wavelength (nm) 

for dip 1 

Resonance Wavelength (nm) 

for dip2 

1.3454 628.479 635.487 

1.3481 628.532 635.535 

1.3503 628.591 635.585 

1.353 628.695 635.78 

1.3553 628.774 635.877 

1.358 628.872 635.933 

1.3604 628.929 636.001 

1.3631 628.992 636.096 

1.3654 629.085 636.181 

1.3682 629.102 636.232 

1.343 1.344 1.345 1.346 1.347 1.348
628.4

628.5

628.6

628.7

628.8

628.9

629.0

629.1

629.2

 

 

(a)

R
e

s
o

n
a

n
c

e
 W

a
v

e
le

n
g

th
 (

n
m

)

Refractive index of NaCl solution (RIU)

 measured data for dip 1

 linear fitting

Y= A+ 140 X

R=0.99

1.343 1.344 1.345 1.346 1.347 1.348
635.4

635.5

635.6

635.7

635.8

635.9

636.0

636.1

636.2

 

 

(b)

R
e
s
o

n
a
n

c
e
 W

a
v
e
le

n
g

th
 (

n
m

)
Refractive index of NaCl solution (RIU)

 measured data for dip 2

 linear fitting

Y= A+ 142 X

R=0.99

Fig [5] the relationships of RI VS resonance wavelength for NaCl at two dips (a) for dip 1, (b) for dip 2 

 



IHJPAS. 36(2)2023 

178 
 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

       

 

 

 

 

 

 

 

 

4.3.1 Resonance wavelength as a function of RI 

          A final step in this research is to draw the relationships between the values of resonance 

wavelengths obtained from the above figures in the tables for both dips Here we can also see that 

there is a direct correlation between the indices of refraction and the wavelength of resonance, 

which is shown by the linear relationship between the two variables. By looking at the Figure (7) 

Table (4) the sensitivities and spectral resolution of macro bending SPR- optical fiber 

immersed into glucose solution 

Resonance dip 
Sensitivity 

(nm/RIU) 

Spectral Resolution 

(RIU) 

Dip 1 38 2.6x10-4 

Dip 2 42 2.3x10-4 

627.5 628.0 628.5 629.0 629.5 630.0
-2500

-2000

-1500

-1000

-500

0

500

1000

(b)

dip 1

 

 

R
e

fl
e

c
ta

n
c

e
 (

R
.U

.)

Wavelength (nm)

635.0 635.2 635.4 635.6 635.8 636.0 636.2 636.4 636.6 636.8
-3000

-2500

-2000

-1500

-1000

-500

0

500

1000

1500

dip 2

(c)

 
 

R
e
fl

e
c
ta

n
c
e
 (

R
.U

.)

Wavelength (nm)

628 630 632 634 636 638

-3000

-2500

-2000

-1500

-1000

-500

0

500

1000

1500

(a)

dip 2

dip 1

 

 

R
e

fl
e

c
ta

n
c

e
 (

R
.U

.)

Wavelength (nm)

 RI=1.3454 RIU

 RI=1.3481  RIU

 RI=1.3503 RIU

 RI=1.353 RIU

 RI=1.3553 RIU

 RI=1.358 RIU

 RI=1.3604 RIU

 RI=1.3631  RIU

 RI=1.3654 RIU

 RI=1.3682 RIU

Fig [6] the relationships between wave length and reflectance recorded by OSA in  RPS for C12H22O11    

at two dips (a) the all spectrum, (b) zoom spectrum of dip 1, and (c) zoom spectrum of dip2.   



IHJPAS. 36(2)2023 

179 
 

below, we can see that there is a clear sense of the least change in refractive index that is reflected 

in the corresponding values of change in resonance wavelengths.  

 

 

 

 

 

 

 

 

 

 

 

 

 

5. Conclusions 

           In examining the results of this research, we can conclude that: 

 Surface Plasmon is very efficient in sensitizing different chemicals with very different 

refractive indices, even very small differences. 

 When Laser was used as a light source instead of the traditional light sources produces 

good results in resolution and sensitivity, as evidenced by the appearance of two distinct 

dips of Plasmon resonance wavelengths. 

 Adding micro bending to the optical fiber leads to a deliberate increase in the loss of light 

in the reaction area, thereby improving the performance of the sensor. 

 

 

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635.4

635.5

635.6

635.7

635.8

635.9

636.0

636.1

636.2

636.3

 

 

(b)

R
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 W

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g

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 (

n
m

)

Refractive index of C
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 measured data for dip 2

 linear fitting

Y= A+ 42 X

R=0.99

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628.4

628.5

628.6

628.7

628.8

628.9

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629.1

629.2

 

 

(a)

R
e

s
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 W

a
v

e
le

n
g

th
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n
m

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Refractive index of C
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H
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O
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 solution (RIU)

 measured data for dip 1

 linear fitting

Y= A+ 38 X

R=0.99

Fig [7] the relationships of RI VS resonance wavelength for C12H 22O11 at two dips (a) for dip1, (b) for dip2 



IHJPAS. 36(2)2023 

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