Study on Vacancy Defect Concentration and Hybrid

Potential of Metal-based Epitaxial Graphene with

Temperature

J H Gao, W Liu

*

, X X Ren and R L Zheng

Engineering Research Center of New Energy Storage Devices and Applications,

Chongqing Chongqing University of Arts and Sciences, Chongqing 402160, P.

R.China

Corresponding author and e-mail: W Liu, liuwei127@126.com

Abstract. This paper investigates the variation of the vacancy defect concentration and

hybrid potential of copper and nickel - based epitaxial graphene with temperature by

considering the existence of vacancy defects. Moreover, we discuss the impact of atomic non-

harmonic vibration on the metal - based epitaxial graphene. First, the concentration of

vacancy defects increases nonlinearly with increasing temperature, and the changing rate of

the vacancy defect concentration of the metal-based epitaxial graphene with temperature is

smaller than that of graphene; Second, the hybrid potential increases with increasing

temperature, but not much; Third, the hybrid potential is independent of temperature without

considering the atomic non-harmonic vibration which has an important influence on the

vacancy defect concentration and the hybrid potential. The higher the temperature is, the

more significant the non-harmonic effects are.

1. Introduction

Epitaxial graphene has attracted the attention of researchers worldwide for its application prospect

[1-4]. Conductivity is one of the most widely used and most important properties. Beside the

experimental research, many literatures have studied the conductivity of epitaxial graphene. In 2013,

Z Z Alisultanov studied the electrical conductivity of electron gas on metal-based and

semiconductor-based epitaxial graphene in Ref. [5]. In 2015, the variation of electrical conductivity

with temperature and thickness of little layer graphene and graphene nanosheets were studied,

indicating that the electrical conductivity gradually decreased with increasing temperature in Ref. [6].

However, these studies did not consider the existence of defects such as vacancies. In 2015, Davydov

made some discussions about the effect of epitaxial graphene vacancy defects on the density of

graphene in Ref. [7], nevertheless, neither the state density of epitaxial graphene on the specific

substrate, nor the relationship between the vacancy defect concentration and the temperature are

studied. At the same time, the physical model is established without taking the non-harmonic

vibration of the atom into account. Therefore, the hybrid potential of graphene is used as a constant

which is irrelevant to the temperature, and the experimental results of the electrical conductivity of

the epitaxial graphene with temperature cannot be explained well. Because of the preparation

194

Gao, J., Liu, W., Ren, X. and Zheng, R.

Study on Vacancy Defect Concentration and Hybrid Potential of Metal-based Epitaxial Graphene with Temperature.

In Proceedings of the International Workshop on Materials, Chemistry and Engineering (IWMCE 2018), pages 194-201

ISBN: 978-989-758-346-9

conditions and the thermal fluctuations of atoms, there are many defects in the epitaxial graphene,

such as vacancies, and the atoms are bound to undergo non-harmonic vibration at the equilibrium

position due to the thermal motion of microscopic particles. It is important to theoretically study the

properties of epitaxial graphene, such as density of state and conductivity, and investigate the

temperature dependent variation of vacancy defects and hybrid potential of epitaxial graphene.

However, the reports about the analytical formula with temperature changing have not yet been seen

so far.

Therefore, in this paper, by using the solid state physics theory and methods, the variation of the

hybrid potential and concentration of vacancy defects in epitaxial graphene with temperature as well

as the effects of non-harmonic vibrations on the variation are studied and compared with graphene.

This study has theoretical significance for revealing the properties of electronic energy states of

materials, and is important for improving material properties and preparing high-performance

electronic materials in practical applications.

2. Physical model and harmonic coefficients and non-harmonic coefficients

The system we studied consists of a single layer of grapheme, which has a hexagonal structure by

adsorbing N carbon atoms on a planar substrate of metal or semiconductor. The area is

LL

,its top

and side views are shown in Figure 1. Take any plane of carbon atoms as the origin of coordinates,

the monolayer graphene plane is the OXY plane, and the Z-axis vertical up to the graphene plane.

Base

Graphene

Figure 1. Top view and side view of epitaxial grapheme.

It is supposed that the ions in the metal substrate are stationary and the electrons are in motion.

Graphene has N carbon atoms, there are n

0

atoms from the normal position to form vacancies due to

the thermal excitation, the vacancy defect concentration is

Nn

0





. Since the graphene carbon

atoms interacting with each other, S.Yu.Davydov [8] gives the interaction between carbon atoms in

graphene

)(d



])(5

9

1[)(

2

1

2

12

2

V

dV

R

Vd





(1)

Where V

2

is the covalent energy of the sp

2

-bond σ bond between two atoms,which is inversely

proportional to the square of the bond length (distance between atoms) d:

222

2

26.3 dBmdV  

,

where m is the mass of free electrons; V

1

is the metallization energy,

10

0

24

)2(10154.0 amR 

, a0 is

the Bohr radius,

32

2





, which is a two-dimensional structure constant.

Due to the thermal motion, the graphene atoms perform non-harmonic vibration in the plane.

)(d



is expand near the equilibrium position of

0

d

and the deviation

0

dd 



is very small, there is



4

2

3

1

2

00

2

1

)()(



d

(2)

Study on Vacancy Defect Concentration and Hybrid Potential of Metal-based Epitaxial Graphene with Temperature

195

where

])(

3

1

1[

3

20

2

1

4

0

2

V

d

V





are the harmonic coefficients, the first and second non-harmonic

coefficients of graphene carbon atom vibration. According to equation (1):

])(

3

10

1[

4

2

1

2

0

V

d





,

])(

3

5

1[

3

16

2

1

3

0

2

1

V

d

V





,

])(

3

1

1[

3

20

2

1

4

0

2

V

d

V





(3)

3. Variations of vacancy defect concentration in epitaxial graphene with temperature

Due to the thermal movement, the carbon atoms of graphene leave the original position to form

vacancy defects. If the metal-based epitaxial graphene is to form a vacancy defect, it is necessary to

overcome the effect of the metal atoms of the base (set the required energy to be

2

u

) and overcome

the effect of other carbon atoms (set the required energy to be

1

u

). Therefore, the energy

u

required

to form a vacancy defect can be considered as the sum of the two, that is,

21

uuu 

, the

experimental value

eVu 5.00.7

1



[9] for the formation of a vacancy defect in graphene has been

given, and

2

u

can be considered as equal to the bonding energy W of the graphene carbon atoms to

the metal atoms of the base, that is,

Wu 

2

. the change in the density of states of the graphene

system due to adsorption, the analytical formula W obtained is [10]:

im

WWW 

(4)

where

m

W

and

i

W

are the metal components and ionization components of the adsorption energy.

)}

2

ln

4

1(]

)23)(2(3

24

222

2

[ln{)3ln21(

2

a

aa

a

aa

mmam

VW

































a

eZ

W

i

44

1

22

0





(5)

Where

2

is called the half-width of the “pseudogap”[11],

eV

76.4

;

ae

ga

4)41(

2

0





,which is the atomic energy level,

g



is the work function of graphene

carbon atom,

eV

g

11.5



[11], a is the length of the adsorption bond, which is approximately equal

to the sum of the radius r

a

of the adsorption atom and the radius r

c

of the carbon atom, that is,

Ca

rra 

; Z is the charge that the adsorbed atom had before it is adsorbed,

 )3ln21(4

m



; V

m

is the interaction energy of the graphene s orbital with the



bond of the adatom atom p orbital, for

graphene-transition metal,

27223

)(

Caaspm

rrmrV  





, the coefficient

95.2





sp

,

0



is the

vacuum dielectric constant.

Graphene forms n vacancy defects, causing the system entropy to increase, the increased amount

is

]!!)!(ln[ nNnNkS

B



, which causes the free energy of the system to change from F

0

to

STnwFF 

0

. When the system reaches equilibrium, the free energy is minimal, considering

that both N and n are large and N >> n, the relationship between vacancy defect concentration α=n/N

and temperature T is obtained as following:

)exp(

Tk

w

B





(6)

IWMCE 2018 - International Workshop on Materials, Chemistry and Engineering

196

4. Variation of epitaxial graphene hybrid potential with temperature

According to the theory of solid physics[12], the hybrid potential is the average interaction energy of

electrons in the hybrid orbital, and it is proportional to the size of the overlapping region of the two-

atom hybrid orbitals. The largest direction of the electron cloud of the carbon four-hybrid orbit points

to the four corners of the tetrahedron (see Figure 2 a).

Supposed that the electron cloud of a hybrid orbital of carbon atom points to the positive x

direction and the maximum direction of a hybrid orbital electron cloud of carbon atom B to the

negative x direction, the hybrid orbits of the two atoms almost completely coincide in the direction at

equilibrium (see Figure 2 (b)). According to Ref. [4], the hybrid potential

22

mdV 





, where



is the undetermined parameter which can be obtained from the hybrid potential of graphene given in

the literature. In equilibrium, the distance between atoms A and B is

0

d

. Because of the non-

harmonic vibration of atoms, the distance between atoms at any temperature is

]1[)(

0

TdTd

l





,

where

l



is the linear expansion coefficient at temperature

T

. When the temperature is moderate, it

is determined by the following formula[13]:

]

)3(

9

3

[

1

2

0

2

21

2

0

1

0

Tk

k

d

B

l











(7)

(a) (b) (c)

Figure 2. Variation of electron clouds caused by non-harmonic vibration.The hybrid orbital

distribution of Carbon

3

sp

hybrid orbital distribution (a), direction equilibrium (b) and vibrational

(c).

Due to the change in the distance between atoms, the overlap region of the electron clouds in the

x-direction hybrid orbitals of the two atoms changes (see Figure 2(c)), causing a change in the

hybridization potential. Since the hybridization potential is inversely proportional to the square of the

atomic distance, the hybrid potential at any temperature is:

2

0

22

0

2

)1(]1([

)(

T

V

Tmd

TV

ll

















(8)

From equations (7) and (8), we can see that the non-harmonic vibration of atoms has an important

influence on the hybridization potential.

Study on Vacancy Defect Concentration and Hybrid Potential of Metal-based Epitaxial Graphene with Temperature

197

5. Effect of atomic non-harmonic vibration on the variation of vacancy defect concentration

and hybrid potential with temperature

The lattice constants

ma

Cu

10-

1061.3 

and

ma

Ni

10-

1061.3 

of copper and nickel are given in Ref.

[14], and the atomic radii

mr

Cu

10

1027.1





and

mr

Ni

10

102445.1





and the radius of carbon

mr

C

10

1077.0





are obtained from the crystal structure. The interaction energy

m

V

between

graphene and the substrate is obtained. Substituting the data of

eV

76.4

and

eV

g

11.5



given in Ref. [11] into formula (5), we can get

m

W

,

i

W

and

im

WWu 

2

for copper and nickel

substrates, respectively. Then, the experimental value

eVu 5.00.7

1



of graphene forming a

vacancy defect is given by Ref. [9], and the energy

u

required to form a vacancy defect is obtained.

For copper base

eVu

Cu

6526.9

; for nickel base

eVu

Ni

6768.9

. Substituting it with

123

.1038.1



 KJk

B

into equation (6), the variation curve of vacancy defect concentration



versus temperature for copper and nickel-based epitaxial graphene is obtained, as shown in Figure

3(b) and Figure 3(c) and Table 1. For comparison, Table 1 and Figure 3(a) also show the change of

the concentration



of vacancy defect in graphene with temperature.

Table 1. Variation of vacancy defect concentration of graphene, copper - based and nickel - based

epitaxial graphene with temperature.

T/K

700

800

900

1000

1100

1200

1300



Graphene(×10

-28

)

0

0.004

7.706

Copper-base(×10

-38

)

0

0.003

4.120

Nickel-base(×10

-38

)

0

0.002

3.302

As can be seen from Table 1 and Figure 3, first, the concentration of vacancy defects increases

with temperature nonlinearly for both graphene and epitaxial graphene. At T<1200 K,

the

concentration of vacancy defects almost reaches 0. However, when the temperature is higher than

1200 K, the vacancy defect concentration sharply increases with increasing temperature. Second, At

the same temperature, the concentration of vacancies in graphene is much greater than that in

epitaxial graphene, and its variation with temperature is much greater. In other words, the graphene is

more likely to form vacancy defects and is more readily be affected by temperature.

The equilibrium bond length of graphene carbon atom d

0

=1.42×10

-10

m, V

2

=12.32eV, V

1

=20.08m,

R=10.08eV.(10

-10

m)

12

are given by Ref. [15], and the simple harmonic coefficient and the first and

second non-harmonic coefficients of the graphene atom vibration are obtained from equation

(3):

22

0

.105388.3



 mJ



,

312

1

.104973.3



 mJ



,

422

2

.102014.3



 mJ



. Ref. [5] also gives

the hybrid potential

eVV 0.2

0



of epitaxial graphene at zero temperature. From equations (7) and

(8), the hybrid potential of epitaxial graphene varies with temperature as shown in Figure 4, where

lines 0, 1 and line 2 are the results of simple harmonic approximation, only the first non-harmonic

term, and the first and second non-harmonic terms, respectively.

IWMCE 2018 - International Workshop on Materials, Chemistry and Engineering

198

(a) (b)

(c)

Figure 3. Variation of vacancy defect concentration of graphene (a), copper - based (b) and nickel -

based epitaxial graphene (c) with temperature.

Table 2. Variation of Silicon (Si) Based Epitaxial Graphene Hybrid Potential with Temperature.

T(K)

300K

500K

700K

800K

1000K

1100K

1300K

V1(ev)

2.009811

2.016391

2.023003

2.026321

2.032982

2.036324

2.043032

V1,2(ev)

2.009811

2.016391

2.023005

2.026323

2.032986

2.036329

2.043040

Study on Vacancy Defect Concentration and Hybrid Potential of Metal-based Epitaxial Graphene with Temperature

199

400 600 800 1000 1200

1.98

2.00

2.02

2.04

2.06

2

1

V (eV)

T /K

0

1

2

0

Figure 4. Variation of Silicon (Si) Based Epitaxial Graphene Hybrid Potential with Temperature.

It can be seen from Table 2 and Figure 4 that in the case of harmonic approximation, the hybrid

potential of epitaxial graphene does not change with temperature. However, if taking into account the

non-harmonic vibration of the atoms, the hybrid potential increases with the increase of temperature,

but the change is not significant. When the temperature rises, the hybrid potential increases by only

1.65%. Also, it is noticed that the higher the temperature is, the greater the difference between the

values of the non-harmonic and harmonic approximations is, that is, the non-harmonic effects

become more significant.

6. Conclusions

In summary, the variation of the concentration and the hybrid potential of metal-based epitaxial

graphene with temperature are studied. First, the concentration of vacancy defects in both graphene

and metal-based epitaxial graphene increases nonlinearly with increasing temperature. The vacancy

defect concentration of epitaxial graphene and its change rate with temperature are more significant

than that of graphene. Second, the hybrid potential increases with the increase of temperature, but the

change is not great. Third, the atomic non-harmonic vibration has an important influence on the

variation of the hybrid potential with temperature. The higher the temperature is, the more significant

the change is, and the more significant the non-harmonic effect is.

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Study on Vacancy Defect Concentration and Hybrid Potential of Metal-based Epitaxial Graphene with Temperature

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