Indonesian Review of Physics (IRiP) Vol. 3, No 1, June 2020, pp. 23-29  
 DOI: 10.12928/irip.v3i1.1530 

 

http://journal2.uad.ac.id/index.php/irip 
23 

 

Effect of Deposition Voltage on Layer Thickness, Microstructure, Cu/Ni Sheet 
Resistivity of Deposition Results by Magnetic Field Electroplating Assisted 
Technique   

2Master Program of Physics Education, Universitas Ahmad Dahlan 

 

Article Info ABSTRACT 

Article History 
Received Jan 12, 2020 
Revised Jun 6, 2020 
Accepted Jun 6, 2020 

The purpose of this research is to make the Cu/Ni thin layer as an alternative to basic 
RTD materials through electroplating methods assisted by magnetic fields. 
Electroplating was carried out with variation in deposition voltage ranging from 1 to 5 
V. The results of this study indicate that the deposition voltage applied to the coating 
affects the thickness, sheet resistivity, and microstructure of the coating. Thickness 
increases with increasing deposition voltage. The diffraction intensity and crystal size 
tend to increase with increasing deposition voltage. The distance between Bragg 
planes after the coating is almost equal for all samples. The highest sheet resistivity 
was obtained in the coating sample with a 4-volt deposition voltage. 

Keywords: 
Electroplating  
Magnetic field  
Sheet resistivity  

To cite this article:  
W. A. Wijanarka and Moh Toifur, “Effect of Deposition Voltage on Layer Thickness, Microstructure, Cu/Ni Sheet 
Resistivity of Deposition Results by Magnetic Field Electroplating Assisted Technique,” Indones. Rev. Phys., vol. 3, 
no. 1, pp. 23–29, 2020. 

 
 
I. Introduction  

Sensor are an important product of environmental 
monitoring. Copper (Cu) and Nickel (Ni) can be 
alternative materials in making low-temperature sensors 
instead of expensive platinum. This is because copper can 
be used to measure temperatures as low as -234.5 0C [1] 
with a linear response. Nickel can also be used as a 
temperature sensor in the range of -200 0C to 320 0C [2].  

Nickel can be superimposed on copper by 
electroplating method to form a thin layer of Cu/Ni. 
Copper and nickel have almost the same atomic size 
(0.1278 Å for copper and 0.1246 Å for a nickel) and both 
have Face Centered Cubic (FCC) lattice shapes [3]. The 
Cu/Ni film formed from the combination of the two 
materials will have a very strong inter-surface adhesion 
force [3]. 

The study that examines the effect of deposition 
voltage on the resistivity and thickness of the layers 
formed in the manufacture of Cu/Cu/Ni/Ni thin films 
with a voltage variation of 1.5 to 5.5 V was done [4]. 
Through this research it is known that the greater the 
deposition voltage the layer thickness and resistivity 
increase. The effect of voltage on the thickness of the 
chrome coating on the steel plate with a variety of the 
voltage of 1.5 to 3.5 V shown that the thickness of the 
layer is directly proportional to the deposition voltage [5]. 
However, the data in the study [5] show that in a certain 
voltage range for deposition times 5, 10, and 15 minutes 
no increase in layer thickness results even though the 

voltage is increased. The studies mentioned above have 
not included the influence of external magnetic fields. 

Electroplating research that includes the influence of 
external magnetic fields in the manufacture of Ni-Co thin 
films proven that the application of an external magnetic 
field caused an increase in mass transport and the rate of 
electro deposition of metals [6]. This study also examined 
the effect of the magnetic field on the regularity of the 
crystal structure on nickel electro deposition. Through 
this research, it is known that by applying a magnetic 
field will prevent holes in the layer caused by the reaction 
of hydrogen evolution so that the layers formed are 
denser. However, the effect of coating resistivity has not 
been studied. Electroplating research on coating copper 
plates with nickel which includes the influence of 
external magnetic fields with variations in deposition 
current density proved that the application of an external 
magnetic field makes the nickel layer formed thicker and 
the sheet resistivity to be higher when compared without 
the application of an external magnetic field [7]. 
However, this research has not yet examined the effect on 
the regularity of crystal structures.  

This research is expected to study thickness, 
microstructure, and sheet resistivity of the Cu/Ni layer 
produced from electrodeposition prosses with a variation 
of deposition voltage and 200 gauss magnetic field-
assisted. 

Jl. Pramuka No. 42, Yogyakarta, Daerah Istimewa Yogyakarta, Indonesia 
*Email: willy.anindito@yahoo.com 

Jl. Magelang Km. 7.5, Sleman, Yogyakarta, Indonesia 

Willi Anindita Wijanarka1* and Moh Toifur 
1SMP Muhammadiyah 1 Mlati 



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e-ISSN: 2621-2889 

 

II. Theory 
The Effect of Deposition Voltage on the 
Electroplating Process 

The relation between current density (J) and 
deposition voltage (V) is illustrated by the graph in Figure 
1 [8]. 

 

 
Figure 1. Graph of the relationship of current density to 

deposition voltage 
 

There is a range of curves in which the current 
density is linearly related to deposition voltage called the 
linear region. There is also a range of curves where the 
current density is exponentially related to deposition 
voltage called the exponential region. The relationship 
between the thickness of the formed layer (δ) to the 
current density (J) satisfies the equation (1). 

 

JtM

NF



  (1) 

 
where: 
t = coating time 
M = molar mass of the deposited element or metal  
N = quantity of electrons transferred 
ρ = layer mass density 
F = Faraday constant (96485.33212 C/mol) 
 
At the low deposition voltage range, the thickness of 

the formed layer increases linearly with increasing 
voltage, then when the voltage is increased the layer 
thickness increases exponentially. 

Ideally, the growth rate of the initial deposit is faster 
than the rate of deposit formation afterward. In conditions 
of too low a voltage, the initial deposit formation takes 
place too slowly, so that the subsequent deposit begins to 
form before the initial deposit is formed perfectly [9]. 
This can result in the formation of deposits in the form of 
rough crystals. Meanwhile, when the voltage begins to 
increase, the rate of initial deposit crystal formation 
begins to increase so that the possibility of deposits 
becoming more fine-grained [9]. 

Too high voltage results in concentration 
polarization, which is the emptying of the solution zone 
around the cathode of ions, so that growth tends to occur 
at a higher zone of concentration which results in deposit 

growth in the form of small groups of crystals, 
resembling trees [9]. Too high a voltage can also result in 
overheating resulting in a burning deposit with a marked 
black color. 

The Effect of Application of the External Magnetic 
Field on the Electroplating Method. By applying an 
external magnetic field to the electroplating process, three 
forces arise in the system that depends on the interaction 
between the moving ions and the magnetic field, namely 

the electrokinetic force ( EF ), magnetic damping force 

( DF ), and the Lorentz force ( LF ) that acting on each ion. 

 Electrokinetic force satisfies the equation (2). 
 

0

d
E

E
F




  (2) 

 

where d  is the charge density of the diffusion 

layer, E  is a non-electrostatic induction field, and 0  

represents the thickness of the diffusion layer. As for the 
magnetic damping force, it is defined as equation (3). 

 

DF v B B    (3) 

 
where   a solution conductivity, v as a velocity of 

ion, and B as magnetic field. The Lorentz force acting on 
each ion satisfies equation (4). 

 

LF qv B   (4) 

 
with q an ionic charge. 
 
If the direction of the magnetic field vector is 

parallel with the ion velocity vector then the Lorentz 
force is zero, whereas for the direction of the magnetic 
field vector perpendicular to the ion velocity vector the 
direction of the Lorentz force is shown in Figure 2. 

 

 

Figure 2. Diagram showing the direction of the Lorentz force 
(direction away from the reader) due to the influence of the 

magnetic field on ions moving perpendicular to the magnetic 
field vector. 

Particles that move under the influence of a constant 
magnetic field in the direction of the velocity vector that 



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e-ISSN: 2621-2889 

 

forms a certain angle to the magnetic field vector have a 
velocity vector component whose direction is 
perpendicular to the magnetic field and velocity vector 
components whose direction is parallel to the direction of 
the magnetic field. With the Lorentz force, the particle 
velocity component whose direction is perpendicular to 
the direction of the magnetic field vector makes the 
particles move in a uniform circular motion. While the 
particle velocity component whose direction is parallel to 
the direction of the magnetic field vector is not affected 
by Lorentz's force so it keeps moving straight. The 
combination of these two kinds of motion causes a 
helical-shaped particle trajectory with an axis parallel to 
the magnetic induction vector or magnetic field strength 

vector ( H ). 
When an external magnetic field is applied, the 

magnetohydrodynamics effect occurs which results in the 
evolution of hydrogen gas. This evolution led to the 
depletion of the Nernst diffusion layer which satisfies 
equation (5). 

 

   
1/3 1/32/3 1/31.59D Rv D nFCB 


  (5) 

 

where D  a nernst diffusion layer, ρ electrolyte 

density, R the working radius of the electrolyte, D the 
electrolyte diffusivity, n as a number of electrons are 
transported during the process, and C the concentration of 
electroactive ions in solution. 

This depletion causes a reduced screening effect that 

increasing in diffusion mass transport ( diffJ ) that 

satisfies equation (6). 
 

   0
/)( eldiff CCDJ    (6) 

 
where D electrolyte diffusivity and Cel electroactive 

ion concentration near the working surface of the 
electrode (in this case the cathode). 

Application of Permanent Perpendicular Magnetic 
Field (PPMF) in the electroplating process in a solution 
medium whose concentration is not uniform gives rise to 

paramagnetic forces ( pF ). While the non-uniform 

magnetic field in the process creates a field gradient force 

( BF ). The paramagnetic force satisfies equation (7). 

 
2

02
m

p

cB c
F






   (7) 

                                            
The field gradient force satisfies equation (8). 
 

0

m
B

cB B
F






  (8) 

 
where m  molar susceptibility, B magnetic field 

strength, c concentration, B  magnetic field gradient, 

c  concentration gradient arising due to changes in 

solution concentration with respect to distance, and 0  

as vacuum permeability. 

 

III. Method 
This research was carried out from January to 

November 2019. Making Cu/Ni samples by 
electroplating method assisted by external magnetic 
fields, thickness measurement, and characterization of 
sheet resistivity for Cu and Cu/Ni produced was carried 
out at the Sentral Laboratory of Physics Education at 
Ahmad Dahlan University. The microstructure 
characterization of XRD from the Cu/Ni thin layer 
produced was carried out in the PSTBM Batan Serpong. 
The object of this study was to observe the effect of 
deposition voltage on the thickness, sheet resistivity, and 
microstructure of Cu/Ni thin films generated by 
electroplating methods assisted by external magnetic 
fields. 

The first step in sample preparation is to create a (10 
x 1.3) cm cutting sticker design on the Cu plate. Parts of 
the plate that are not attached to the sticker are dissolved 
using FeCl3 solution, then cleaned with aquades. The 
electroplating process is carried out with variations in 
Voltage (V), the Voltage used is 1, 2, 3, 4, and 5 V in the 
electroplating process with 200 gauss magnetic field. The 
electroplating time is 60 seconds. The size of Ni plate 
used for coating is (12.6 x 5.3) cm. The resulting sample 
is first tested for coating thickness by first measuring the 
mass of the sample before and after coating. Layer 
thickness (  ) is determined by equation (9).  

 

W

A



  (9) 

 
Where W the difference between the mass of the 

sample after coating and before the coating (gram), ρ the 
density of the sample (gram/cm3), and A the surface area 
of the sample (cm2).  

Second, determine the sheet resistivity ( sR ) using 

voltage (V) and current (I) data measured through a four-
point probe through the equation (10).  

 

ln 2
s

V
R

I


  (10) 

 
Third, analyze the microstructure by looking at the 

peak x-ray intensity data generated through the XRD test. 
Crystal size ( sg ) determine by the Debye-Scherrer 

equation that shows in equation (11).  
 

0.9

cos
sg

FWHM




   (11) 

      
where λ the wavelength of the X-ray used, FWHM 

the width of the diffraction peak at the position of half the 



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maximum diffraction intensity, and θ the diffraction 
angle.  

Fourth, determine the distance between Bragg 
planes ( d ) through equation (12). 

 

2 sin
d




            (12) 

 

IV. Results and Discussion 
Determination of Layer Thickness 

Coatings are carried out 5 samples coded WAW-01, 
WAW-02, WAW-03, WAW-04, and WAW-05 that 
indicates the sample is coated with deposition voltage 1, 
2, 3, 4 and 5 V, respectively. The mass measurements of 
the samples were carried out before coating (mCu) and 
after coating (mCu/Ni) whose results are shown in Table 1. 

 

Tabel 1. The mass of the sample before and after coating 

Magnetic 
field 

(gauss) 

Deposition 
Voltage 

(V) 
mCu (g) mCu/Ni (g) 

200 

1 1,89468 1,89970 
2 1,81606 1,83142 
3 1,87654 1,90220 
4 1,81730 1,86204 
5 1,89880 1,96412 

Then determine the thickness of the formed Ni layer 
( ) using equation (11). The graph of the relationship 
between the thickness of the nickel layer formed and the 
deposition voltage shown in Figure 3. 

 

Figure 3. Graph of the Relationship between Thickness of Ni 
Layer Formed to Deposition Voltage 

At deposition voltage 1, 2, 3, 4, and 5 V 
successively produced nickel thickness of (7.40 ± 0.07; 
22.66 ± 0.07; 37.85 ± 0.07; 65.99 ± 0.07; 96.35 ± 0.07) × 
105 cm. Through linear regression obtained the curve 
equation that represent the relationship between thickness 
and deposition voltage shown in equation (13). 

 

4 4
1.90951 10 1.423631 10B

 
      (13) 

 
By looking at the gradient that is positive it can be 

seen that the thickness of the layer formed is directly 
proportional to the applied deposition voltage. This is due 
to the increase in deposition voltage which will increase 
the number of electrons flowing from the anode to the 
cathode through the conductor. This causes an increase in 
the amount of ion anode material formed so that the mass 
of the anode material superimposed increases which also 
means the thickness increases. By remember that the 
greater the voltage indicates the higher current density, 
this result is suitable that obtained in previous studies that 
the thickness of the layer increases with increasing 
current density [10]. 

 

Microstructure Test 
The microstructure test of the coating was done 

through XRD testing by firing the Cu K-alpha 1 rays 
which have a wavelength of 1.54060 Ǻ on the sample. X-
ray diffraction intensity (I) data was taken in the 
scattering angle range (2θ) of 0ᴼ to 100ᴼ. After phase 
identification, Ni and Cu phases are obtained at the first 
two peaks shown in figure 4. 

 

 

Figure 4. Results of the identification of Ni and Cu phases 

  Increasingly sharp of graph diffraction intensity 
indicates the increasing amount of diffraction counts that 
the detector receives. This is as a result of the 
increasingly orderly and lengthy arrangement of the 
crystal-structure atoms. The graph of diffraction intensity 



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e-ISSN: 2621-2889 

 

for the first peak is shown in Figure 5, where for the 
second peak show in Figure 6. 

0

2000

4000

6000

8000

10000

12000

1 2 3 4 5

D
if

fr
a

ct
io

n
 i

n
te

n
si

ty
 

(a
rb

it
ra

ry
 u

n
it

)

Deposition voltage (V)
 

Figure 5. Graph of the relationship between diffraction 
intensity and deposition voltage for the first diffraction pea 

 

0

2000

4000

6000

8000

10000

1 2 3 4 5

D
if

fr
a

ct
io

n
 i

n
te

n
si

ty
 

(a
rb

it
ra

ry
 u

n
it

)

Deposition Voltage (V)
 

Figure 6. Graph of the relationship between diffraction 
intensity and deposition voltage for the second diffraction peak 

By remembering the results of the layer thickness 
test and observing the graphs in Figures 5 and 6 it is 
known that the diffraction intensity tends to increase with 
the increase of thickness and deposition voltage. This is 
because by increasing the element of Ni on the Cu 
substrate will increase the amount of Ni crystals formed. 
By increasing the intensity of nickel diffraction the 
resistivity of thin film will increase because the higher 
intensity of diffraction indicates a more orderly 
arrangement of atoms [11].         

 In the Graph of the relationship between diffraction 
intensity and deposition voltage for the first diffraction 
peak, the intensity decrease at 4 V deposition voltage. 
This is probably due to non-uniformity of the thickness of 
Ni that coated, then the X-ray that is fired is not hitting on 
the part of the sample that represents the characteristics 
real sample.       

Then the average crystal size is determined from the 
crystal size for the first and second Ni diffraction peaks. 
The crystal size for each diffraction peak is determined 
by equation (11). The relationship of the average Ni 
crystal size to the deposition voltage is shown in the 
Figure 7. 

It can be seen in the graph in Figure 7 that crystal 
size increase with the increase of deposition voltage and 

thickness. This is consistent with the results of the 
previous study that increasing the number of coatings 
increases the size of the crystal [12]. The increase in 
crystal size will have an impact on decreasing sheet 
resistivity [13]. 

 

 

Figure 7. Graph of relationship between average Ni crystal size 
and deposition voltage. 

Then the distance between the Bragg plane (d) is 
determined at the peak of the first and second Ni 
diffractions, each graph shown in Figures 8 and 9. 

2,0402

2,0404

2,0406

2,0408

2,0410

2,0412

2,0414

2,0416

D
is

ta
n

ce
 b

e
tw

e
e

n
 B

ra
g

g
 p

la
n

e
s 

(Å
)

Figure 8. Graph of relationship between distance between 
Bragg planes for first Ni diffraction peak and deposition 

voltage. 

 

 

Figure 9. Graph of relationship between distance between 
Bragg planes for second Ni diffraction peak and deposition 

voltage. 



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The distance between Bragg planes satisfies 
equation (12). Through this equation, it appears that the 
distance between the Bragg planes is influenced by the 
diffraction angle of 2 theta. Based on the diffraction peak 
data obtained by the XRD test, there was no phase shift in 
all sampel which meant the diffraction angle showed 
almost the same value for all sampel. This makes the 
distance between the Ni Bragg planes obtained is also 
almost equal for all samples.  

The distance between these Bragg planes also 
affects the magnitude of sheet resistivity. The smaller the 
distance between Bragg planes will increase the amount 
of electric current flowing thereby increasing 
conductivity [14]. By remembering that resistivity is 
inversely proportional to conductivity, it means that the 
greater distance between Bragg planes will result in 
greater resistivity.   

 

Sheet Resistivity 
Samples WAW-01, WAW-02, WAW-03, WAW-

04, and WAW-05 were successively coated with 1, 2, 3, 4 
and 5 V deposition voltage. Sheet resistivity test was 
carried out to all sample before and after coating using a 
four-point probe.    Measurement of voltage and a current 
flowing in the sample is carried out five times at five 
different points with an input voltage made constant at 6 
V. The sheet resistivity  used is the average sheet 
resistivity of the sheet resistivity for each measurement 
point. The sheet resistivity of each sample before and 
after the coating is shown in table 2. 

 
Table 2. Sheet Resistivity of sample before and after coating 

Deposition 
Voltage (V) 

Before coating: 
Rs ± SRs (Ω/sq) 10-5 

After coating: 
Rs ± SRs (Ω/sq) 10-5 

1 4,4125  0,0001 4,5003  0,0001 
2 4,4061  0,0001 4,4831  0,0001 
3 4,4083  0,0001 4,5344  0,0001 
4 4,4120  0,0001 4,5599  0,0001 
5 4,3988  0,0001 4,5266  0,0001 

 
The graph of the relationship between sheet 

resistivity after coating and deposition voltage is shown 
in Figure 10. 

It can be seen in Table 2 that after the coating is done 
there is an increase in the sheet resistivity of the sample. 
This is probably due to the impurity of Cu samples by Ni 
whose resistivity is higher. 

There is a tendency for an increase in diffraction 
intensity, crystal size, and distance between Bragg planes 
with increasing deposition voltage. The increase in 
distance between Bragg planes has a more dominant in 
influencing the sheet resistivity value for deposition 
voltage 2 to 4 V so that the sheet resistivity value tends to 
increase in the deposition voltage range.  While at 1 and 5 
V deposition voltage, the diffraction intensity and crystal 
size factor are more dominant in influencing the 
resistivity value so that the sheet resistivity value 
decreases at the deposition voltage. 

4,47E-05

4,48E-05

4,49E-05

4,50E-05

4,51E-05

4,52E-05

4,53E-05

4,54E-05

4,55E-05

4,56E-05

4,57E-05

0 1 2 3 4 5 6

S
h

e
e

t 
R

e
si

st
iv

it
y

 (
o

h
m

/s
q

)

Deposition Voltage (V)
 

Figure 10. Graph of sheet resistivity relationship to deposition 
Voltage. 

 
Another factor that causes mismatches between sheet 

resistivity data to crystal size, diffraction intensity, and 
distance between Bragg planes is the lack of precision 
displaying the voltage value read on the voltmeter. Non-
uniformity in the thickness of the deposited Ni layer also 
affects, because this results in a 4 point probe not always 
able to measure at points that can represent the 
characteristics of the actual sample. 

 

V. Conclusion 
The effect of deposition voltage assisted by 

magnetic fields on the variables of the coating samples 
studied are as follows: (1). The thickness of the formed 
Ni layer increases with the increase of deposition voltage, 
(2). The regularity of Ni crystal-structure atoms increases 
with the increase of thickness and deposition voltage, the 
lowest regularity of the crystal-structure atoms obtained 
in the deposited sample with a deposition voltage of 1 V. 
(3). The average Ni crystal size increases with the 
increase of deposition voltage. The smallest Ni crystal 
size in the coating sample with a deposition voltage of 1 
V, (4). Spacing between Bragg planes is almost equal for 
all samples, (5). The highest sheet resistivity was 
obtained from the sample that coated with a 4 V 
deposition voltage. 

 

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