Ibn Al-Haitham Jour. for Pure & Appl. Sci. 34 (1) 2021 
 

12 
 

 

  

 

 

Study the Effect of Annealing on the Structural Properties of Zinc Oxide 

Films by Electrolysis Technique 
 

Aws A. Mahdi                                                      Sameer A. Makki 

 

Department of Physics, College of Education for Pure Science  (IbnAl-Haitham),University of  

Baghdad, Baghdad, Iraq. 

ausalimahdi1994@gmail.com 

 

 

 

 

Abstract 

     Zinc oxide films (ZnO) are prepared by an electrolysis technique and without vacuum and 

then annealed atvarious temperatures (300,400,500)
O
C for an hour. The structural analysis 

performed by X-Ray diffraction (XRD) shows,dominant orientation of this films is plane 

(101), has a hexagonal structure and  polycrystalline pattern and it was is found that the 

crystal size increases(24,29) nm at annealing temperatures (300, 400)° C, but the crystal size 

decreases to (20 nm) at annealing temperature (500 ° C). As the results of a surface nature 

study of these films showed by examining the atomic force microscope (AFM), the grain  size 

increases from (60.79 to 88.11) nm, and the surface roughness increases from  (1.99 to 2.34) 

nm when increasing annealing temperatures is (300,400,500)°C, respectively.   

Keywords: thin film, ZnO, electrolysis, annealing temperature. 

 

1.Introduction 

    Zinc oxide (ZnO) is a semiconductor compound of the II-VI family, [1]. Zinc has 

characteristics such as the presence of an optical energy gap (3.37eV) and a large exiton 

binding energy (60 meV) at room temperature [2,3]. Where it has absorbance, it is located 

in the UV zone and has good conductivity at n-type[4]. It has another property that can be 

polycrystalline or single crystal films and even random, in a random order if the films are 

exposed to a temperature of less or equal to (180) °c, to consider this degree is the degree of 

critical material [5,6]. When exposed to heating in the air (without vacuum ), change color 

for ( Zno) compound from white to yellow color,When cooling, the compound returns to 

white color again, This is due to the loss of a few number of oxygen at high temperatures 

[7]. As well as not dissolving in water or alcohol, the compound may be soluble in certain 

Ibn Al Haitham Journal for Pure and Applied Science 

Journal homepage: http://jih.uobaghdad.edu.iq/index.php/j/index 

 

Doi: 10.30526/34.1.2574 

Article history: Received,19, December ,2019, Accepted  27,April,2020, Published in January 2021 

 

mailto:ausalimahdi1994@gmail.com


  

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Ibn Al-Haitham Jour. for Pure & Appl. Sci. 34 (1) 2021 

 

acids, namely acetic acid and mineral acids, etc .[8]. Zinc Oxide films are used for the 

manufacture of certain devices, including condensers, solar cells, gas sensors, purple and 

blue light emission devices and pressure sensors [9,10].  Zinc oxide films prepared with 

various techniques are  spray pyrolysis[11], magnetron sputtering [12] , electron beam 

evaporation [13], sol-gel coating[14] and chemical vapor deposition [15] .In this search, the 

effect of annealing temperatures )300, 400 and 500)  ℃  on the structural properties of zinc 

oxide films has been identified. 

2.Experimental Procedure 

1-The hydrochloric acid is diluted by adding (10 ml) of acid to (90 ml) of distilled water . 

2-This diluted solution is placed in a beaker and considered an electrolyte solution. 

3- Two slides of zinc are immersed in the electrolyte solution and the first slide is connected 

to the positive electrode of the source and the other slide to the source electrode 

4-passing an electric current with a value of ((I = 127mA(, voltage (5V), and the distance 

between the two slides  )  d = 1.5 cm). 

5- The time taken to prepare the solution is (10sec). 

6-by drop casting method, it is deposited on the glass slides and then annealed these films  at 

different temperatures (300,400,500)℃ for an hour. 

3.Results and Discussion 

3.1 X-ray diffraction 

    By examining the X-ray diffraction, it was found that the (ZnO) films had a polycrystalline 

structure of hexagonal type when compared with the International Center for Diffraction Data 

for zinc oxide. Measurements found that the dominant peak of this film is  plane(101), and it 

was found that the highest intensity is at the plane (101), i.e. direction perpendicular to the 

base, and this tendency in crystallization was due to the van der Drift model called the 

Survival of the fastest model, as suppose the process of nucleation is established  has more 

than one direction in the  first stages of the film growth, then these trends began to compete 

during its growth, so the faster nuclei will continue to grow, while the growth of the other 

nuclei stops, and this explains the growth of the ZnO membranes towards (101), i.e. direction 

perpendicular to the base, because this the trend is the fastest growing,  , And the intensity 

increases when the annealing temperature increases between (300, 400) ° C, but the intensity 

decreased at the temperature ((500 ° C) and this means a decrease in crystalline regularity, as 

well as a decrease in the value of the Full Width at Half Maximum purpose (β) at annealing 

temperature (300,400)℃ and increased at annealing temperature (500 ° C(, as shown in 

Figure 1 and Table 1 



  

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Ibn Al-Haitham Jour. for Pure & Appl. Sci. 34 (1) 2021 

 

 

Figure 1.Represents the X-ray diffraction patterns of the annealed zinc oxide films at different temperatures a 

(300 °C) b (400 °C)c-)500 °C( 

Table 1 shows the distance between the planes and the X-ray diffraction angle values for the 

crystalline planes (101,002,100) at the different annealing temperatures. 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

25 30 35 40 45 50 55 60 65 70

in
te

n
si

ty
(a

rb
.u

n
it

) 

2Ɵ(degree) 

(1
0

0
) 

(0
0

2
) 

1
0

1
 

C 

b 

a 

hkl)) d(hkl)A⁰ 2Ө (degree) Sample 
(101) 

(002) 

(100) 

2.475920 

2.603320 

2.814300 

36.2521 

34.4211 

31.7694 

ZnO (ICDD) 

(101) 

(002) 

(100) 

2.48695 

2.61277 

2.83139 

36.0867 

34.2936 

31.5734 

ZnO at 300°C 

(101) 

(002) 

(100) 

2.47723 

2.60566 

2.81905 

36.2333 

34.3901 

31.7153 

ZnO at 400°C 

(101) 

(002) 

(100) 

2.48637 

2.61056 

2.82982 

36.0955 

34.3235 

31.5914 

ZnO at 500°C 



  

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Ibn Al-Haitham Jour. for Pure & Appl. Sci. 34 (1) 2021 

 

3-1-1 Synthetic properties parameters 

1-A distance between crystalline planes 

The distance between the crystalline planes was calculated and compared with the zinc oxide 

international card, and it was found to be  close.The reason for this difference between the 

international card and the results is, firstly, the oxygen deficiency (away from the chemical 

equivalence) and,  secondly, the effect of stress due to the thermal expansion coefficient of the 

membrane( 7 × 10−6/℃) and the thermal expansion coefficient of the glass base( 4.6 × 10−6/℃) are 

incompatible, and the value of the distance between atomic planes (d) we found to decrease at the 

annealing temperatures (300,400) ° C but increase at the temperature of( 500 °C), as shown in Table 1. 

2-  Crystalline lattice constants 

The crystal lattice constants (ao,co) for the zinc oxide films prepared in this waywere found to be close 

to the International Card. (ICDD). At the annealing temperature (300,400) ° C we found that it 

decreased but increased at the annealing temperature of 500 °C، As shown in Table 2 

Table 2.the values of the crystal lattice constants (ao, co) at temperatures (300,400,500 )°C, 

respectively. 

 

3-crystalline Size 

The crystal size of the zinc oxide films was calculated and it was found that crystal size increased with 

increasing annealing temperatures (300,400) and the reason for increasing of the crystal size is a 

decrease (FWHM) because the relationship between them is inverse and the effect of annealing 

temperature led to the abolition of some planes and defects that exist after the growth and 

rearrangement of the crystalline grains takes place, as the granules take sufficient energy for growth 

and arrangement within the crystalline lattice , but I have decreased at the annealing temperature 

(500℃).This led to an increase in crystalline defects and consequently a decrease in crystal size، as 

shown in Table 3. 

 

 

 

 

 

 

 

hkl)) d hkl(A⁰) C o  (A⁰) ao(A⁰) Sample 

(002) 
(100) 

2.603320 
2.814300 

5.20664 3.24967 ZnO (ICDD) 

(002) 
((100 

2.61277 
2.83139 

5.2254 3.269 ZnO at 300C⁰ 

(002) 
(100) 

2.60566 
2.81905 

5.21132 3.2551 ZnO at 400C⁰ 

(002) 
((100 

2.61056 
2.82982 

5.22112 3.26759 ZnO at 500C⁰ 



  

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Ibn Al-Haitham Jour. for Pure & Appl. Sci. 34 (1) 2021 

 

                          Table 3.shows  Full Width at Half Maximum  values  and grain size 

 

 

 

3-2 Atomic Force Microscopy 

     By examining the (AFM) to investigate the surface topography (nature) we know the effect 

of annealing at various temperatures is (300,400,500)°Con zinc oxide films and as shown by 

the grain size and surface roughness, we found that the granular size values increase within 

the nanoscale range (60.79-88.11)nm, and an increase in the surface roughness values (1.99-

2.34) nm, which leads to an increase in absorbance. This indicates the possibility of using 

these films in the manufacture of solar cells, as shown in Table 4 and Figure 2. 

Table 4. Grain size and roughness values for the surface of zinc oxide films at different 

annealing temperatures (300,400,500) °C . 

Root mean 

square(nm) 

Roughness surface(nm) Average diameter(nm) Sample 

2.3 

 

1.99 60.79 ZnO at 300 
O
C 

2.5 2.14 70.68 ZnO at 400 
O
C 

2.83 2.34 88.11 ZnO at 500 
O
C 

 

  

hkl Dav(nm) ß=FWHM(degree) 2Ө (degree) Sample 

101 24 0.37160 36.0867 

 
ZnO at 300C⁰ 

101 29 0.30690 36.2333 

 
ZnO at 400C⁰ 

101 20 0.45070 36.0955 

 
ZnO at 500C⁰ 

a 



  

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Ibn Al-Haitham Jour. for Pure & Appl. Sci. 34 (1) 2021 

 

 
 

 
 

 

Figure 2 .Results of examination of the atomic force microscopy of the zinc oxide films at different 

annealing temperatures a- (300 °C) b- (400 °C) C (500 °C). 

4.Conclusions 

     The zinc oxide films show that the dominant direction is plane)101(.When the annealing 

temperature increases to 500 C, this intensity decreases at this temperature, and this means the 

membranes have decreased degree of crystallization. It is found that when the annealing 

temperature increases, the surface roughness increases and the absorption increases, making 

the membranes good to use as a solar cell. 

 

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