CHEMICAL ENGINEERING TRANSACTIONS 

VOL. 56, 2017 

A publication of 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Jiří Jaromír Klemeš, Peng Yen Liew, Wai Shin Ho, Jeng Shiun Lim
Copyright © 2017, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-47-1; ISSN 2283-9216

Morphology and Optical Properties of Zinc Oxide 
Nanoparticles Synthesised by Solvothermal Method 

Widiyastuti Widiyastuti*,a, Siti Machmudaha, Tantular Nurtonoa, Sugeng Winardia, 
Ratna Balgisb, Takashi Ogib, Kikuo Okuyamab 
aDepartment of Chemical Engineering, Institut Teknologi Sepuluh Nopember, Kampus ITS Sukolilo, Surabaya, Indonesia 
bDepartment of Chemical Engineering, Hiroshima University, Higashi-Hiroshima, Japan  
 widi@chem-eng.its.ac.id 

Zinc oxide (ZnO) nanoparticles were successfully synthesised in solvothermal batch reactor using zinc acetate 
as precursor and ethanol as solvent, without any surfactant addition. Commercial batch Teflon reactor of 21 
mL was used and filled 80 % capacity with 0.1 M zinc acetate solution. The reactor was heated in an oven and 
held at a constant temperature for 12 h. In order to investigate the temperature effect on the characteristics of 
the generated particles, the reactor temperatures were varied at 120, 140, 160, and 180 °C. The powder was 
characterised by its morphology, crystallinity, and photoluminescence spectra via scanning electron 
microscopy (FE-SEM, Hitachi), x-ray diffraction (XRD, Phillips), and photoluminescence spectrometer 
(Simadzu) respectively. Spherical nanoparticles were generated for particles synthesised without LiOH 
addition into precursor. By adding 0.14 M LiOH into the precursor, rod particles were obtained with an aspect 
where the ratio (length to diameter) of particle increased with temperatures. Based on the X-ray diffraction 
analysis, wurtzite structure of ZnO in a hexagonal phase was formed. Neither impurities nor other crystalline 
phases were observed in the samples. The crystalline size increased from 19 to 28 nm by increasing the 
reactor temperature from 120 to 180 °C. LiOH addition led to decrease in the crystalline size at the same 
reactor temperature. Their crystalline size increased from 16 to 23 nm by increasing the reactor temperature 
from 120 to 180 °C. Photoluminescence intensity increased with temperatures. LiOH addition was able to shift 
the photoluminescence emission spectra peak from wavelength of 421 nm to 457 nm by excitation at 
wavelength of 250 nm. It corresponded to the dominant emission shifted from violet to blue by adding LiOH 
during the synthesis.  

1. Introduction

ZnO particles have been widely applied in the field of optics and optoelectronics because they have wide 
bandgap semiconductor compound (Eg = 3.37 eV) with a large exciton binding energy (60 meV) (Morkoç and 
Özgür, 2009). Comparing to that of the thermal at room temperature at 26 meV, ZnO particles exhibit a strong 
exciton binding energy correspond to a valuable photonic material in the UV-blue region (Ghoshal et al., 
2008). Due to its good electrical and optical properties, thermal and chemical stability, non-toxicity, and 
relatively low price as metal-oxide semiconductors, ZnO particles have been applied as photocatalyst, solar 
cell windows, sensor for volatile organic compound (Saito et al., 2014) and specifically, sensor for nitro-
organic compound (Casa et al., 2016). These wide range of electrical and optical properties highly depend on 
both the shape and size of nanostructured particles.  
Many methods have been developed to control the properties of ZnO nanostructured particles. Fine spherical 
particles were produced by spray pyrolysis method. Aluminium as dopant was selected to control the electrical 
properties of ZnO film (Widiyastuti et al., 2012). Nano-sized ZnO particles have been synthesised using low 
pressure spray pyrolysis (Hidayat et al., 2008) and pulse combustion spray pyrolysis (Widiyastuti et al., 2007). 
ZnO nanostructured using green process of sonochemical reaction method was also reported that pulse wave 
of ultrasonic irradiation affected the photoluminescence intensity and photocatalytic activity (Widiyastuti et al., 
2015).  

 

   

DOI: 10.3303/CET1756160

 
 
 
 
 
 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Widiyastuti W., Machmudah S., Nurtono T., Winardi S., Balgis R., Ogi T., Okuyama K., 2017, Morphology and 
optical properties of zinc oxide nanoparticles synthesized by solvothermal method, Chemical Engineering Transactions, 56, 955-960  
DOI:10.3303/CET1756160   

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Another green process to produce ZnO nanostructures is solvothermal method. A solvothermal process can 
be defined as a chemical reaction in a closed system in the presence of a solvent at a temperature higher than 
that of the boiling point of such a solvent. Solvothermal process has been of interest due to its mild synthesis 
conditions, simple processes, low cost and simple equipment, and inherent stability. The size and morphology 
of ZnO nanoparticles can be controlled by adjusting the ratio of the two selected solvents, in the template-free 
solvothermal method (Lian et al., 2012). Solvothermal method can produce pencil-like ZnO microrod (Liu et 
al., 2012). Other experimental parameters such as reaction temperature, reaction time, and solvent, precursor, 
and additive/surfactant types might affect the growth of novel nanostructures of ZnO which led to the 
controlled characteristics of the generated ZnO particles.  
In this study, the effect of temperature in producing ZnO nanoparticles in a solvothermal method on the 
generated particle morphology and photoluminescence properties was investigated. Ethyl alcohol and zinc 
acetate dihydrate were selected as the solvent and the precursor. The effect of lithium hydroxide added in the 
solution was also examined.   

2. Experimental 

Zinc acetate dihydrate (Zn(CH3COO)2.2H2O 99.5 %, Merck) was dissolved in ethanol by stirring to prepare 
zinc salt solution. In order to prepare zinc salt solution with lithium hydroxide addition, zinc acetate and lithium 
hydroxide solutions were mixed to obtain the final solution containing 0.1 M zinc acetate and 0.14 M lithium 
hydroxide. Commercial batch Teflon reactor of 21 mL was used and filled 80 % capacity with precursor 
solution. Reactor was heated in an oven and held at a constant temperature for 12 hours. The oven was 
turned off for natural cooling to room temperature. The oven temperature was set at 120, 140, 160 and 180 °C 
to investigate the effect of temperature. The generated particles were separated from the liquid by 
centrifugation. Then, they were washed by distillate water for three time to make sure the contaminants were 
eliminated. After that, the particles were placed in crucible boat and were dried in oven at temperature 60 °C 
for 6 h. The powder was characterised by its morphology, crystallinity, chemical bonding, and 
photoluminescence spectra via field emission scanning electron microscopy (FE-SEM, Hitachi), x-ray 
diffraction (XRD, Phillips), and photoluminescence spectrometer (Simadzu). 

3. Results and discussion 

The morphologies of the generated ZnO particles at various temperatures were analysed by FE-SEM. Figure 
1(a) - (d) show the morphology of particles synthesised at 120, 140, 160, and 180 °C, without LiOH addition. 
The temperatures were selected under subcritical condition, in which the synthesis temperature was larger 
than that of normal boiling temperature of ethyl alcohol (78.37 °C) as a solvent and lower than that of its 
critical temperature (241 °C). Spherical particles were produced and the sizes increase with temperatures. In 
addition, for temperature of 180 °C, the particle sphericity decreased. The average size are 32, 38, 42, and 60 
nm for synthesis temperatures of 120, 140, 160, and 180 °C.  
The particles morphology was deformed from spherical to nanorod when LiOH was added to the precursor as 
depicted in Figure 2(a) - (d) for synthesis temperatures of 120, 140, 160, and 180 °C. The diameter and length 
of nanorod increased by increasing the temperature from 120 to 140 °C. The size decreased steeply with the 
increase of temperature from 140 to 180 °C. Table 1 shows the length, width, and ratio of length and width 
(L/W) for particles synthesized by adding LiOH at varied temperatures. 
In the solvothermal process, the formation of ZnO nanostructures follows two consecutive stages, nucleation 
and secondary growth processes. Nucleation process is indicated by the formation of Zn(OH)2 colloids from 
the reaction of OH- ions and Zn2+ ions in the ethyl alcohol. As the supersaturation reaches, Zn(OH)2 colloids 
precipitates and then decomposes into ZnO nuclei at elevated temperature. It is assumed that LiOH is 
involved in the secondary growth of ZnO nuclei in elongating structures. The addition of LiOH can increase the 
supersaturation degree. This process led to the growth of elongated structures and the roughness of the 
surface (Hu et al., 2010).   

Table 1: Length, width, and ratio of length and width (L/W) for particles synthesised by adding LiOH at varied 
temperatures 

Temperature (°C) Average Length, L (nm) Average Width, W (nm) L/W 
120 17.21 50.53 2.93 
140 36.04 87.75 2.43 
160 25.14 59.19 2.35 
180 23.24 55.11 2.37 

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Figure 1: SEM images of the generated particles using precursor without LiOH addition for reactor 
temperatures of (a) 120 °C, (b) 140 °C, (c) 160 °C, and (d) 180 °C 

Figure 3(a) and 3(b) show the XRD diffractograms of ZnO particles prepared at varied temperatures without 
LiOH addition and with LiOH addition. It can be shown that the diffractograms were in good agreement with 
that of JCPDS 36-1451 corresponding to the hexagonal wurtzite crystal structure of ZnO. No other impurities 
peaks observed in the XRD diffractograms revealed that the crystalline ZnO formed well for all samples. The 
addition of LiOH did not affect the diffractograms which agreed well with the ZnO standard of JCPDS 36-1451. 
However, LiOH addition caused the (0 0 2) lattice plane at 2θ = 34.364° was higher than that of (1 0 0) lattice 

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plane at 2θ = 31.732°. The presence of Li+ in the precursor can slow down the growth speed in one direction 
and increase it in another direction (Ehrentraut et al., 2006).   

 

Figure 2: SEM images of the generated particles using precursor with 0.14 M LiOH addition for reactor 
temperatures of (a) 120 °C, (b) 140 °C, (c) 160 °C, and (d) 180 °C 

 

Figure 3: XRD patterns of the generated particles synthesised at various temperatures (a) without LiOH 
addition and (b) with 0.14 M LiOH addition 

The crystalline size, dc, was estimated using Scherrer equation based on the highest peak in XRD 
diffractograms correspond to (1 0 1) lattice plane at 2θ = 36.252°. The crystalline size of the generated ZnO 
nanostructures increase with temperature. The addition of LiOH inhibited the growth of ZnO crystal resulting in 
smaller crystalline size than that of ZnO without LiOH addition. Figure 4 shows the effect of synthesis 
temperature on the crystalline size of the generated ZnO particles. 
Photoluminescence emission spectra of ZnO samples that excited at wavelength of 250 nm are shown in 
Figure 5. ZnO particles synthesised without LiOH addition have the highest emission peak at 421 nm 
corresponding to violet emission spectra. The photoluminescence intensities have linear correlation with 
synthesis temperature. LiOH added into the precursor was able to shift the photoluminescence emission peak 
to 457 nm corresponding to blue emission spectra. Besides photoluminescence spectra can be used to 
evaluate the optical properties, it can be used to study the defect characteristics. The characteristic of near-
band-edge emission of free exciton recombination process causes ultra-violet/violet emissions whereas blue 
emission was caused by association with oxygen vacancies.    

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Figure 4: Effect of LiOH addition and solvothermal temperature on the crystalline size of the generated 
particles 

 

Figure 5: Photoluminescence spectra of the generated particle at varied temperature and compared to 
particles that generated by LiOH addition during the synthesis 

4. Conclusions 

ZnO nanoparticles were produced using solvothermal method. Particles characteristics were affected by 
synthesis temperature and addition of LiOH into the precursor. Spherical and nanorod nanoparticles were 
produced by without LiOH and with LiOH, added into precursor. XRD analysis of all the generated particles 
was in good agreement with hexagonal wurtzite crystal structure of ZnO. The size of particles and the 
crystalline increased with temperatures and decreased with the addition of LiOH. Photoluminescence 
emission spectra peak was shifted from wavelength of 421 to 457 nm corresponding to violet to blue emission 
by adding LiOH into precursor when they were excited at wavelength of 250 nm.  

Acknowledgments  

The authors want to thank Ms. Hikmatul Auliyah and Ms. Palupi Nisa for assistance in the experiments. 
Research Grant sponsored by Ministry of Research Technology and Higher Education, Republic Indonesia 
under research collaborations and international publications scheme (No. 078/SP2H/LT/DRPM/II/2016) is 
gratefully acknowledged. 

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