19 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

Young’s Modulus Calculation of Some Metals  

Using Molecular Dynamics Method Based on the Morse Potential 

 

Fitriana Faizatu Zahroh
1.a

, Iwan Sugihartono
2
 and Ernik D. Safitri

1 
 

1
Department of Physics. Faculty of Mathematics and Natural Sciences, University of Jember, Jl. 

Kalimantan No. 37, Jember 68121, Indonesia 

2
Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Negeri 

Jakarta, Jl. R.Mangun Muka Raya, RT.11/RW.14, Rawamangun, Kec. Pulo Gadung, Kota 
Jakarta Timur, Daerah Khusus Ibukota Jakarta 13220, Indonesia 

a
fitrianazahrah@gmail.com 

 
 
Abstract. It has been investigated computationally Young's modulus of some metals: nickel, copper, 
silver, gold, and aluminum. The offset method can graphically determine Young's modulus property by 
determining the elastic region based on the straight line intersection formed at a 0.2% strain against the 
stress-strain curve. In this simulation work, Young’s modulus calculation was performed by using the 
LAMMPS molecular dynamics software. The interatomic potential used to represent the interactions 
among atoms of materials in this simulation is the Morse potential. The metals under-investigated in this 
work are nickel, copper, silver, gold, and aluminum, and we got the results are 209.2 GPa, 110.8 GPa, 
83.8 GPa, 79.2 GPa, and 70.3 GPa, respectively. The Young's modulus of the materials was also 
computed as temperature variations from 300K to the melting point to determine the effect of temperature 
on Young's modulus, and it is tensile strength. From our work we can found that the higher the 
temperature, the lower Young's modulus value. In addition, it can be seen that nickel metal has good 
temperature resistance. This is evidenced by the change in the nickel-metal phase near its melting point. 

 
Keywords: Molecular Dynamics, Morse Potential, Young’s Modulus, Stress-Strain 

Introduction 

The development of new/novel materials utilizing computational and simulation methods is one 
of the creative ways to optimize and streamline material research before direct experimental 
synthesis. Material research by reviewing the microscopic structure of materials can be used to 
predict materials macroscopically. By modeling and simulating materials in micro sizes, the 
macro-physical properties of materials can be estimated using Young’s modulus of copper, 
silver, gold, aluminum, and nickel metals. 
 
The elasticity property is the tendency of solid material to return to its original shape before 
permanently deformed [1]. Deformation in a solid material occurs when a force is applied to it. A 
measure of the degree of elasticity of a material indicates the material's resistance to elastic 
deformation due to external forces known as Young's modulus [2]. 
 
Investigation of Young's modulus of metallic materials has ever also been previously carried out 

by Camprubi [3] for nano-sized copper wire material. Ferguson [4] also studied the Young 

modulus of pure aluminum metal-based on EAM potential.  

 



  
 
 
 
 
 

20 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

Even many studies developed the EAM potential for metals. In our work, the calculation of 

Young's modulus is carried out using the molecular dynamics method based on metals' Morse 

potential. The fitting process is carried out to get proper morse potential parameters based on 

available experimental data (at 300K) before further evaluation to determine Young's modulus's 

temperature dependence. The use of Morse potential will simplify our simulation as a 

preliminary study of metals. We use the LAMMPS molecular dynamics code for simulating the 

phenomena (lammps.sandia.gov).   

 
Materials and Methods 
 
1. Young’s Modulus 

The Young’s modulus of the material is closely related to material characteristics based on the 
degree of stiffness when external forces influence it. Materials with large Young's modulus are 
relatively non-elongated so that tremendous stress is required to produce deformation [5]. 
 
Young's modulus of material can be determined from a macroscopic perspective by knowing the 
ratio of stress to strain, known as Hooke's law. 
 

  
      

      
 

 

 
 

   

     
 (1) 

 
where: 
E = young’s modulus (GPa) 
σ = stress (GPa) 
ɛ = strain 
F = tensile force on metal (eV/Å) 
A = surface area of metal (Å

2
) 

   = length of metal before being subjected to a load (Å) 
  = length of metal after being subjected to a load (Å) 
   = change in length of metal before and after being subjected to a load (Å) 
 
Calculation of Young's modulus of pure metal is determined using the offset method by 
calculating the stress's slope to the elastic region's strain curve, namely the strain 0.002 [9]. The 
limit of the elasticity of the material is known as the yield stress (Yield). The slope area's 
determination starts from zero to the yield point, that is, when the stress-to-strain curve is no 
longer linear. The Young (E) modulus values of some metals are represented by Young's 

modulus (Y), according to Table 1 below. 
 

Table 1. Young's modulus values of some pure metals 

Material Young’s modulus (Pa) References 

Aluminum 7.0 x 10
10

 

[5] 

Brass 9.0 x 10
10

 
Copper 11.0 x 10

10
 

Kerona Glass 6.0 x 10
10

 
Lead 1.6 x 10

10
 

Nickel 21.0 x 10
10

 



  
 
 
 
 
 

21 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

Material Young’s modulus (Pa) References 

Steel 20.0 x 10
10

 
Gold 7.9 x 10

10
 [6] 

Silver 8.25 x 10
10

 [4] 

 
Experimentally, the study of the effect of temperature on Young's modulus can be carried out 
using a tuning fork made of pure aluminum metal as the material [7]. Based on this research, it 
can be seen that the increase in material temperature affects Young's modulus value. The 
higher the temperature of the material, the lower Young's modulus value.  
 
The load applied to the material continuously will cause the stress and strain relationship to be 
non-linear. This area is called the plastic area, where the material cannot return to its original 
state when the applied load is removed. After passing the material's yield point, the stress will 
continue to increase for a specific limit called maximum stress. In this condition, the material can 
accept. The maximum stress is usually referred to as the tensile strength or UTS (Ultimate 
Tensile Strength) [8]. After passing through the tensile strength, the material's ability to accept 
loads will decrease until the material breaks (fracture).  
 
2. Metals  

Each metal has different characteristics so that several tests can be carried out, for example, 
tensile testing, impact tests, and hardness tests to determine the properties of the metal, 
especially its mechanical properties [9]. The following are some explanations of the metal 
materials used. 
 
a) Copper 

Copper is a metal that has an FCC crystal structure with a lattice constant of 3.6062 Å [10] and 
a melting point of 1358 K [11], which is often applied as nanowires. Copper has Young's 
modulus of 110 GPa [5] and is often used in uranium alloy compositions as an aircraft 
component.  
 
b) Silver 

Silver is a metal with a relative mass of 107.87 grams/mol, composed of an FCC crystal 
structure with a lattice constant of 4.0729 Å [10]. Based on its mechanical properties, silver has 
a lower Young's modulus value than copper and nickel, namely 82.5 GPa at 293 K [4]. 
 
c) Gold 

Gold is an ideal metallic material for wires and electrodes at the nanoscale [12]. At the size of 
nanoparticles, gold and silver metals have been widely used as sensors, catalysis, 
biochemistry, optics, and electronics [13]. Gold is composed of an FCC crystal structure with a 
lattice constant of 4.0588 Å [14] and has a melting point of 1338 K [11]. 
 
d) Aluminum 

Aluminum is a light metal with an atomic mass of 26.981 grams/mol and has resistance to 
corrosion [15]. The metal comprises an FCC crystal structure with a lattice constant of 4.0305 Å 
[10], Young & Freedman [5] stated in their book that aluminum metal has Young's modulus 
value of 70 GPa. Aluminum will undergo a phase change to become liquid at a temperature of 
933.5 K [11]. 
  



  
 
 
 
 
 

22 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

e) Nickel 

Nickel is a metal that has an FCC crystal structure with a lattice constant of 3.5214 Å [10] and is 
often used in industry as a building block for steel. One of the advantages of nickel is that it has 
corrosion resistance properties. However, in a pure state, it is soft so that when combined with 
several other metals such as chrome and iron, it will be the right choice to form hardened 
corrosion-resistant steels. The metal has a relative mass of 58.71 grams/mol [16]. Nickel is very 
easy to combine with other metal elements, so its use is essential as a constituent of metal 
alloys for corrosion and heat resistance considering its high melting point is 1728 K [16]. 
 
3. Molecular Dynamics Methods 

Molecular dynamics simulations predict the physical quantities of interactions at the atomic or 
molecular level based on the designed material model and based on the input simulation d ata 
given [17]. The research method used in this research is the classical molecular dynamics 
method, which can solve or find solutions to Newton's equations of motion using a potential 
function by the results of the atomic trajectory solution, which in this study is based on Morse's 
potential. Based on this, there is a relationship between the macroscopic properties of matter 
and the interactions at the atomic or molecular level.  
 
4. Interactions Among Atoms 
At the microscopic scale, each atom that is close to each other will interact with each other due 
to the atoms' forces. So it requires an interaction force between atoms, which is equivalent to 
the interaction potential used. The selection of interaction potentials greatly determines the 
results of the simulation performed. Rapaport [18] stated two main principles in the interaction 
between atoms: attractive forces and repulsive forces between atoms. First, if the atomic pairs 
are separated at a close distance, the resultant interaction forces will repel each other. Second, 
if the atomic pairs are separated at a great distance, the resultant interaction forces will attract 
each other. However, at a certain distance, the interaction styles that occur will cancel each 
other out so that the resultant interaction force will be zero. There is a dependence between the 
attractive interactions and the repulsive interactions between atoms on the potential energy, 
according to Figure 1 [5]. 
 

 
Figure 1. The dependence between attractive interactions and repulsive interactions between 

atoms on potential energy 
 
The interaction potential between atoms consists of a position function representing the atoms' 
potential energy when located in a particular configuration. This can be described using the 
relative position of an atom to another atom, which can be explained by the equation: 
 



  
 
 
 
 
 

23 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

U(r1.r2....) = V1 + V2 + V3 (2) 

 
The force that makes the atoms in an atomic system interact unbound when the atoms are 
close together or neighboring can survive in composing the crystal is the Van der Waals’s force 
[19]. 
 
5. Morse Potential 

Apart from the Lennard Jones potential and the EAM (Embedded atomic Method), another 
potential is often used in molecular dynamics simulations, namely the Morse potential. This 
potential has been widely used to explain the various properties of crystals. The characteristics 
of these crystals include cohesive energy, the lattice constant, compressibility, and elasticity 
constant. The usual Morse potential function is written in the following equation:  
 
U(rij) = D{exp [-2α (rij-r0)] - 2exp [α(rij-r0)]} (3) 

 
where, 
U(rij) = interaction energy between atoms i and j separated at a distance (eV) 
D = potential well depth and is the energy parameter (eV) 

α = potential width controlling parameter (Å-1) 
r = distance between atoms (Å) 
r0 =equilibrium distance between atoms i and j at minimum potential (Å) 
 
The Morse potential parameters of some pure cubic metals are composed of the FCC crystal 
structure, according to Table 2. 
 

Tabel 2. Morse potential parameters are suitable for some pure metals 

Metal Lattice constant α (Å
-1

) D (eV) r0 (Å) 
Cu 3.6062 2.369 0.1716 2.5904 
Ag 4.0729 2.389 0.1534 2.9060 
Au 4.0588 3.174 0.1588 2.8764 
Al 4.0305 2.335 0.1139 2.8798 
Ni 3.5214 2.544 0.2091 2.5218 
Pb 4.9356 -2.398 0.0849 3.5022 

 
6. Equation of Motion 
In classical molecular dynamics, each atom and molecule is treated as a point mass that 
satisfies Newton's motion equations. The simulation is based on classical mechanics for a 
system of N atoms interacting through a potential function. This equation of motion is known as 
Newton's second law, namely: 
 

     
    

   
 (4) 

 

   is the net force in newtons on atom i, determined from the negative gradient of potential 
energy based on atomic coordinates. 
 
                 (5) 



  
 
 
 
 
 

24 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

 
N is the number of atoms in the simulation [3]. 

 
Information about the correlation between the microscopic and macroscopic states of the 
material can be explained using an ensemble. The system under review is simulated in an 
isobaric-isothermal ensemble. In this ensemble, the number of particles, pressure, and 
temperature as macroscopic properties of the system can be maintained at a constant value 
while the volume of the system changes. Volume changes occur as a result of the load on the 
system. 
 
Results and Discussion 
 

The selection of the potential function and its parameters is essential for obtaining simulation 
result data suitable for the experiment. To get results consistent with experiments on macro-
sized materials, the system is conditioned to a pressure of 1 atm. The results obtained in this 
study are: 
 
1. Correction of Morse Potential Parameters (D, α and r0) 

Correction of the Morse potential parameter in the pure metal system was carried out to 
determine Young's modulus value at a temperature of 300K. The Young modulus value data 
was obtained, which was by the experimental data. Furthermore, these three parameters are 
used to determine Young's modulus value with temperature variations leading to its melting 
point. These parameters are obtained by running the simulation based on the input given. 
Based on the correction of the Morse potential parameter that has been done. It is obtained that 
the parameter values D, α, and r0 are appropriate for the case under study. Parameter D shows 
the potential well depth expressed in energy units (eV). The parameter α is a parameter 
controlling the potential width expressed in (Å

-1
). Meanwhile, r0 shows the equilibrium distance 

between atoms i and j when the minimum potential is expressed in units (Å). Parameters D, α, 
and r0 on the calculated Young's modulus, along with the percentage of the discrepancy, are by 
Table 3.  
 

Tabel 3. Morse potential parameter to Young's modulus value of the pure metal 

Material D (eV) α (Å
-1

) r0 (Å) E (GPa) Discrepancy (%) 

Cu 0.1716 2.538 2.5940 110.8 0.7 
Ag 0.1534 2.491 2.9060 83.8 1.6 
Au 0.1588 2.357 2.8767 79.2 0.2 
Al 0.1139 2.743 2.8798 70.3 0.4 
Ni 0.2110 3.080 2.5218 209.2 0.4 

 
2. Determination of Young’s Modulus Value of Pure Metal at 300 K 
The calculation of Young's modulus values for the five materials is carried out based on the 
deformation system obtained. The deformation system simulates the material's mechanical 
properties by using a tensile test on the x-coordinate vector so that the system changes shape 
and size. The deformation system consists of stress (σ) at coordinates (X, Y, Z) and strain (ε). 
The following is the stress-strain curve generated from the five materials deformation system at 
a temperature of 300K. According to Figures 2,3,4,5 and 6. 
 



  
 
 
 
 
 

25 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

 
Figure 2. Pure copper stress-strain curve at a temperature of 300K 

 
Based on Figure 2, it is shown that the limit of the elasticity area occurs at a stress of 4.9 GPa 
with a strain of 0.05. Also, it can be seen that the tensile strength of the copper metal system is 
11.4 GPa. which occurs at a strain of 0.13. Figure 2 shows that the system experiences a sharp 
stress drop when it passes through the tensile strength region of up to 4.5 GPa, which occurs in 
the strain area between 0.14 to 0.16. This shows that in this area, the system has almost lost 
resistance to a given load. At a strain of 0.17 to 0.3, it can be seen that the system has a small 
load resistance, which is indicated by a stress value range of 2.5 to 3 GPa. 
 

 
Figure 3. Pure silver stress-strain curve at 300K 

 
Based on Figure 3, it is shown that the limit of the elasticity area occurs at a stress of 3.1 GPa 
with a strain of 0.04. In addition, it can be seen that the tensile strength of the copper metal 
system is 6.9 GPa, which occurs at a strain of 0.1. Figure 3 shows that the system has 
experienced a sharp stress drop from the tensile strength area to 0.7 GPa, which occurs in the 
strain area between 0.11 to 0.12. However, at a strain of 0.13 to 0.3, it can be seen that the 
system goes into a state where the resistance to loading is zero. This indicates that the system 
has fractured. 
 



  
 
 
 
 
 

26 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

 
Figure 4. The stress-strain curve of pure gold at a temperature of 300K 

 
Based on Figure 4. it is shown that the limit of the elasticity area occurs at a stress of 3.4 GPa 
with a strain of 0.04. In addition, it can be seen that the tensile strength of the copper metal 
system is 7.1 GPa, which occurs at a strain of 0.1. Figure 4.8 shows that the system has 
experienced a sharp stress drop from the tensile strength area to 0.8 GPa, which occurs in the 
strain area between 0.12 to 0.14. However, at a strain of 0.15 to 0.3, it can be seen that the 
system goes into a state where the resistance to loading is zero. As with silver material, it 
indicates that the system has fractured. 
 

 
Figure 5. The stress-strain curve of pure aluminum at a temperature of 300 K 

 
Based on Figure 5, it is shown that the limit of the elasticity area occurs at a stress of 2.6 GPa 
with a strain of 0.04. In addition, it can be seen that the tensile strength of the copper metal 
system is 5.3 GPa, which occurs at a strain of 0.09. In Figure 4.9. it can be seen that the system 
has experienced a sharp stress drop from the tensile strength region to 0.3 GPa, which occurs 
in the strain area between 0.1 to 0.11. However, at a strain of 0.11 to 0.3, it can be seen that the 
system goes into a state where the resistance to loading is zero. This shows that after a sharp 
drop in stress, the system fractures. 
 



  
 
 
 
 
 

27 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

 
Figure 6. The stress-strain curve of pure aluminum at a temperature of 300K 

 
Based on Figure 6, it is shown that the boundary of the elasticity area occurs at a stress of 8.3 
GPa with a strain of 0.04. Also, it can be seen that the tensile strength of the copper metal 
system is 18.9 GPa, which occurs in a strain of 0.12. Figure 6 shows that the system 
experiences a sharp stress drop from its tensile strength area to 5.3 GPa, which occurs in the 
strain area between 0.12 to 0.14. However, at a strain of 0.15 to 0.3. it can be seen that the 
system has a small load resistance, with a stress value range of 4 to 5 GPa. Based on Figures 
2,3,4,5 and 6, it can be concluded that the increase in the tensile strength of the material is 
proportional to the increase in the Yield stress of each material. Also, the copper and nickel 
metal systems do not fracture as in silver, gold, and aluminum at the end of the simulation.  
 
Referring to the Morse potential parameter in Table 3, the Young modulus value for each pure 
metal material at a temperature of 300K is obtained along with the value of the discrepancy , 
according to Table 4. 
 

Tabel 4. Young's modulus value of the pure metal at a temperature of 300K 

Material reference (GPa) stimulation (Gpa) Discrepancy (%) 

Cu 110.0 110.8 0.7 

Ag 82.5 83.8 1.6 

Au 79.0 79.2 0.2 

Al 70.0 70.3 0.4 

Ni 210.0 209.2 0.4 

 
Based on the simulation results, the system's stress has a GPa scale, considering the material 
used is nano-sized metal, which has a regular arrangement of atoms. Whereas for materials 
such as macro-sized metals and composites, the stress produced has an MPa scale, which is 
undoubtedly far from the simulation results. This is because the order of the atoms is not as 
good as the system in the simulation.  
 
Based on Table 4, it is known that the Young gold modulus has a much better level of accuracy 
than other metals. The smaller discrepancy value of gold indicates this compared to other 
metals, namely 0.2%. The lowest level of accuracy occurs in silver metal, where the 
discrepancy value is 1.6%. However, each of the Young modulus values above can be said to 
be following experimental data considering that the discrepancy value obtained is less than 2%. 



  
 
 
 
 
 

28 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

The accuracy of Young's modulus values for these five materials is highly dependent on the 
suitability of the Morse potential parameters used. 
 
3. Young’s Modulus at Various Temperature Variations 

In addition to the temperature of 300K, the determination of the Young modulus value of pure 
metal using molecular dynamics methods is also carried out based on temperature variations. 
The temperature used starts from 300K to close to the melting temperature. Temperature 
variation is carried out in one direction, from the smallest to the largest value. This was done to 
determine the resistance of the material to loading during extreme temperatures. Knowing 
Young's modulus value shows how much stress the material can accept up to the elasticity limit 
of the material. For that, a stress-strain curve is needed for each temperature variation. Figure 7 
shows the stress-strain curve for pure copper metal with temperature variations. 
 

 
Figure 7. The stress-strain curve in pure copper with temperature variations 

 
Based on Figure 7, it can be seen that the increase in temperature applied to copper metal 
causes a decrease in the value of its tensile strength. The more significant the decrease in 
tensile strength, the easier the material is deformed. The graph shows that copper metal 
undergoes a phase change to become liquid at a temperature of 1273K before reaching its 
melting point at 1358K. This is evidenced by the absence of a stress-strain curve pattern as at 
the previous temperature. 
 
At a temperature of 1273K, the calculation of Young's modulus value cannot be carried out 
considering that the stress-strain curve is linear along the x-axis with a stress value of 0 GPa 
along with the strain. At an initial temperature, such as at a temperature of 300 K, it can be seen 
that there is a sharp drop in stress when the load continuously exceeds its tensile strength. This 
shows that the metal is almost losing its ability to defend itself from deformation due to the load 
received until, in the end, the metal experiences continuous elongation with relatively constant 
stress. However, when the metal temperature has approached its melting temperature, such as 
at 1223K, the stress gradually decreases. This indicates that at this temperature, copper metal 
has a low resistance to deformation. 
 



  
 
 
 
 
 

29 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

In addition to copper metal, the resistance of the material to a given load with temperature 
variations in silver metal is shown in Figure 8. 
 

 
Figure 8. The stress-strain curve in pure silver with temperature variations 

 
The increase in temperature applied to silver metal causes a decrease in the value of its tensile 
strength, as in Figure 8. The graph shows that silver metal undergoes a phase change to 
become liquid at a temperature of 873K, long before reaching its melting point, which is at 
1235K. This is evidenced by the absence of a stress-strain curve pattern as at the previous 
temperature. At a temperature of 873K, the calculation of Young's modulus value cannot be 
carried out considering that the stress-strain curve is linear along the x-axis with a stress value 
of 0 GPa along with the strain.  
 

 
Figure 9. Stress-strain curves on pure gold with temperature variations 

 
The increase in temperature applied to the gold metal also causes a decrease in the value of its 
tensile strength, as shown in Figure 9. The graph shows that the gold metal undergoes a phase 
change to become liquid at a temperature of 873K, long before it reaches its melting point at 
1338K. This is evidenced by the absence of a stress-strain curve pattern like at the previous 
temperature. At a temperature of 873K, the calculation of Young's modulus value cannot be 
carried out considering that the stress-strain curve is linear along the x-axis with a stress value 



  
 
 
 
 
 

30 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

of 0 GPa along with the strain. At a temperature of 823K, the voltage drops slowly. This 
indicates that at this temperature, gold metal has low resistance to deformation. 
 

 
Figure 10. Stress-strain curves on pure aluminum with temperature variations 

 
Based on Figure 10, it can be seen that the increase in temperature applied to aluminum metal 
also causes a decrease in the value of its tensile strength. The graph shows that aluminum 
metal undergoes a phase change to become liquid at a temperature of 723K before reaching its 
melting point (933.5K). At a temperature of 723 K, the calculation of Young's modulus value 
cannot be carried out considering that the stress-strain curve is linear along the x-axis with a 
stress value of 0 GPa along with the strain. 
 

 
Figure 11. The stress-strain curve in pure nickel with temperature variations 

 
Based on Figure 11, the metal's resistance to deformation at low temperatures, which is 
between 300K and 573K, is still quite good. This is evidenced by the metal's ability to maintain 
the strain that occurs at the point of its tensile strength, which is still quite good. On the other 



  
 
 
 
 
 

31 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

hand, at temperatures of 1423K to 1673K, the metal is seen to experience a relatively more 
significant decrease in tensile strength than at the previous temperature.  
 
Figure 11 shows that nickel-metal undergoes a phase change at a temperature of 1723K. 
Young's modulus can be determined when the material is still in a solid phase. Solid material 
has a tremendous inter-atomic binding energy compared to the liquid and gas phases. This is 
related to the orderly arrangement of atoms so that the bonds between atoms that occur are 
also stronger. In the liquid phase, the arrangement between atoms is more irregular. That is why 
it is difficult to determine the Young modulus when it approaches its melting point. The 
relationship between the Young modulus values of pure metals and their temperature variations 
is shown in Figure 12.  
 

 
Figure 12. The relationship between Young’s modulus values of pure metals to temperature 

variations 
 
Based on Figure 12, it can be seen that each pure metal has decreased with the increase in 
temperature. Microscopically, the liquid phase of the material has a greater distance between 
atoms than the solid phase. This causes the binding force between atoms in the liquid phase to 
be smaller than in the solid phase. 
 
Visualization of the Effect of Temperature 

The temperature variations are given to each pure metal material affect the structure of the 
material. This is indicated by the percentage change in crystal structure at any given 
temperature variation. Based on the simulation results that have been carried out. When given 
temperature variations under the effect of a given loading, the behavior of the material can be 
seen in the visualization display using the OVITO software. Based on this visualization, the 
system state of each material can be seen. The state of the system starts from a temperature of 
300K, as in Figure 13, to a state where the material undergoes a phase change to become 
liquid, as in Figure 14. 
 
 



  
 
 
 
 
 

32 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

  
(a) (b) 

Figure 13. Visualization of nickel (a) before loading with (b) after loading at a temperature of 300 
K 

 
Figure 13 shows that at a temperature of 300 K, nickel metal is composed of a uniform crystal 
structure with a percentage of the FCC crystal structure of 100%. In contrast to the case when 
the crystal structure of nickel metal is no longer uniform after loading. This was evidenced by 
the CNA display, which showed the percentage of HCP's crystal structure was 14.3%, the FCC 
was 55.8%, and 30% for the crystal structure that was undefined. Green shows the FCC's 
crystal structure, red shows the crystal structure of the HCP, and gray shows the crystal 
structure that is undefined. At a temperature of 300 K, it can be seen that the atoms making up 
the nickel-metal material are still in the solid phase. This is indicated by the absence of a cavity 
or free space in the simulation box, where the space indicates that the metal system has 
undergone a phase change, although not entirely. In addition to the temperature of 300 K, the 
nickel-metal state at 1723 K can be observed based on Figure 14.  
 

  
(a) (b) 

Figure 14. Visualization of nickel (a) before loading with (b) after loading at a temperature of 
1723 K 

 
Figure 14 shows that at 1723 K, nickel metal is composed of a small portion of the FCC crystal 
structure, namely 1% and 99% of the crystal structure is undefined. In contrast to the case when 
after loading, the nickel-metal's crystal structure becomes uniform, namely 100% composed of 
an undefined crystal structure. At a temperature of 1723 K, it can be seen that the atoms 
making up the nickel-metal material have undergone a phase change from solid to liquid. This is 
indicated by a cavity or free space on the edge of the simulation box. Microscopically, metals in 
the solid phase are composed of atoms with binding energy greater than those in the liquid 
phase. This shows that the atoms' binding energy making up the nickel-metal at a temperature 
of 1723 K has a relatively small value, causing the distance between the atoms and the volume 



  
 
 
 
 
 

33 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

of the system to be much larger than in the solid phase. The profile of the effect of temperature 
variations on copper, silver, gold, and aluminum materials is the same as for nickel metal. The 
other four materials' visualization is shown in the visualization of the effect of temperature on the 
pure metal material system. 
 
Conclusions 

The research's success can be reviewed based on Young's modulus value of the five materials 
according to the experimental results, namely with a discrepancy value of less than 2%. Also, 
the accuracy of selecting the interatomic potential function based on the appropriate parameters 
is an essential factor in obtaining precise and accurate results, which in this study uses the 
Morse potential, which is suitable for metallic materials in the solid phase. The simulation of the 
calculation of Young's modulus value is carried out using the molecular dynamics method. This 
method can be developed in more complex cases, one of which is the stiffness of alloys and 
composites. 

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34 

 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 2, Issue 1, page 19 – 34   
 
 

Submitted  : March 11, 2019 
Accepted  : April 21, 2019 
Online  : May 2, 2019 
doi : 10.19184/cerimre.v2i1.20557 

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