{The Synthesis of porous indium phosphide with nickel oxide crystallites on the surface:}


http://dx.doi.org/10.5599/jese.1301    593 

J. Electrochem. Sci. Eng. 12(4) (2022) 593-601; http://dx.doi.org/10.5599/jese.1301    

 
Open Access : : ISSN 1847-9286 

www.jESE-online.org 

Original scientific paper 

Synthesis of porous indium phosphide with nickel oxide 
crystallites on the surface 
Yana Suchikova, Ihor Bohdanov1, Sergii Kovachov1, Andriy Lazarenko1,  
Iryna Bardus1, Alma Dauletbekova2, Inesh Kenzhina3 and Anatoli I. Popov2,4 
1Berdyansk State Pedagogical University, Berdyansk, Ukraine  
2L. N. Gumilyov Eurasian National University, Nur-Sultan 010008, Kazakhstan 
3Kazakh-British Technical University, Almaty 050000, Kazakhstan 
4Institute of Solid State Physics, University of Latvia, Riga LV-1063, Latvia 

Corresponding author: yanasuchikova@gmail.com; Tel.: +38(066)338-78-64 

Received: February 15, 2022; Accepted: June 26, 2022; Published: July 6, 2022 
 

Abstract 
In this paper, the technology of synthesis of crystallites and nanocrystallites of nickel oxide on the 
surface of indium phosphide is described. This technology consists of two stages. In the first stage, 
porous indium phosphide is formed on the surface of a single crystal of indium phosphide. The 
formation of such a porous layer provides better adhesion to the surface of the sample. The second 
stage involves the preparation of the solution that contains nickel ions, application of this solution 
to the surface of porous indium phosphide, followed by annealing. As a result, NiO/NiC2O4∙2H2O/por- 
-InP/mono-InP structure was formed. Surface morphological parameters were obtained using 
scanning electron microscopy and EDX-analysis of chemical composition. Chemical analysis 
confirmed the partial formation of nickel oxide from nickel oxalate layer by thermal annealing. Using 
scanning electron microscopy, it has been established that the crystallites have a large scatter in 
diameter, but they may be divided into three characteristic groups: macro-; meso- and nano-
crystallites. Such structures may find prospects for application in electrochemical capacitors and 
lithium-ion batteries. Further research is needed for methodology improvement to obtain structures 
with predetermined controlled properties. 

Keywords 
Nickel oxalate; annealing; electrochemical etching; coating; EDX spectrum 

 

Introduction 

Metal oxide semiconductors have recently been widely researched due to the prospects of their 

application as sensors, lasers, and in a wide range of photon detection and electronic devices, solar 

energy, etc. [1,2]. Among such types of materials, MgO [3], Al2O3 [4], KNbO3 and LiNbO3 [5,6], TiO2 

[7,8], ZnO [9] and SnO2 [10] are the most studied. Thus, zinc oxide was grown using the epitaxial 

method on ZnSe substrate, as researched in paper [11]. In another paper [12], the authors 

demonstrated the prospects for the application of SnO2 to create solar cells. 

http://dx.doi.org/10.5599/jese.1301
http://dx.doi.org/10.5599/jese.1301
http://www.jese-online.org/
mailto:yanasuchikova@gmail.com


J. Electrochem. Sci. Eng. 12(4) (2022) 593-601 SYNTHESIS OF POROUS InP WITH NiO CRYSTALLITES 

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At present, the great and close attention of many research groups is focused on new materials 

such as Ga2O3 [13,14], ZnGa2O4 [15] and BaGa2O4 [16]. Among the top prospect materials is also NiO 

due to its chemical stability and unique electrochemical properties. Nickel oxide has a band gap in 

the range of 3.6 - 4.0 eV that offers a great value for photovoltaic devices, supercapacitors, sensors, 

etc. [17,18]. Nickel oxide nanostructures, in particular nanotubes, nanoparticles and nanowires, 

offer even a greater value [19].  

The widely used methods of obtaining nanoparticles and nanostructures of nickel oxide are 

methods of precipitation, dehydration and oxidation by steam-based etching [20]. However, these 

methods are usually quite complex and expensive and require special equipment. Therefore, at 

present, there is a necessity for development of simple and inexpensive methods of nickel oxide 

synthesis. Another problem in the growth of oxide semiconductors is the choice of substrate. The 

fact is that crystal lattices mismatch, while the chemical stability of many semiconductors prevents 

the adhesion to the substrates, significantly affecting the quality of the resulting layers. 

In this paper, we research the growth of nickel oxalate (NiC2O4∙2H2O) and subsequently crystals 

of nickel oxide (NiO) on indium phosphide (InP) substrate using a two-stage technology. 

Experimental  

The structures were formed in two stages. The first stage is the formation of a porous pattern on 

the surface of monocrystal indium phosphide. This step is necessary for better adhesion to the 

monocrystalline indium phosphide (mono-InP) substrate of nickel-containing compounds. As it is 

known, porous layers have fewer dislocations under the surface, which hinders the excess stress 

[21]. Therefore, such porous layers are considered to be ‘soft’ substrates, and they are becoming 

more popular [22]. The second stage is the deposition of nickel oxalate and synthesis of nickel oxide 

crystallites on the porous surface of InP (por-InP). 

Formation of porous layer on mono-InP 

The first stage was intended to form pores on the surface of indium phosphide. Monocrystalline 

high-alloy (S) indium phosphide samples of n-type conductivity with surface orientation (111) were 

used. Before the experiment, the samples were cleaned, degreased in acetic solution, and dried in 

a stream of oxygen. 

The samples were then electrochemically etched in hydrochloric acid solution in a standard two-

electrode electrolytic cell with a platinum cathode. The aqueous-alcoholic solution (C2H5OH : H2O = 

= 1:2) of hydrochloric acid with an acid concentration of 7 % was used as the electrolyte. A few drops 

of bromic acid were added to the solution. It should be noted that this electrolyte composition is 

not sufficiently selective for the (111) surface of monocrystalline n-InP. Such choice of electrolyte is 

conditional on the fact that the task was not to obtain a dense porous layer in this experiment 

[23,24]. The main purpose was to ensure surface roughness by etching the surface, as well as bulk 

defects to remove excess crystal stress. 

Etching was carried out using the constant voltage of 5 V for 5 min. In the course of etching, a 

large number of bubbles were observed on the semiconductor wafer. Bubbles shall be the result of 

oxygen evolution. As a rule, gas bubbles cause disruption of the oxides locally formed on the surface 

of the semiconductor. In order to reduce the effect of bubble generation, the electrolyte solution 

was periodically stirred with the use of a mechanical stirrer. Following the etching, the samples were 

dried in a stream of oxygen for 2 h, washed in deionized water and kept outdoors for 3 days. The 



Y. Suchikova et al. J. Electrochem. Sci. Eng. 12(4) (2022) 593-601 

http://dx.doi.org/10.5599/jese.1301 595 

samples became dark gray and lost their full gloss. This provides evidence of texturing of the crystal 

surface and formation of the extended macroroughness. 

Formation of nickel particles on the surface of por-InP 

For the purpose of NiO formation, the two-stage method was used, which consisted of the 

hydrothermal method and annealing. All substances used in this experiment had a high purity class 

and did not require additional purification. 

At the first stage, five portions (mass) of NiCl2∙6H2O were dissolved in a mixture containing two 

portions of ethylene glycol and one portion of deionized water. The resulting mixture was heated in 

a beaker to 40 °С. Then, it was stirred with a magnetic stirrer for 20 min. 1 g of Na2C2O4 was added 

to the resulting solution. The resulting suspension was stirred with a magnetic stirrer for 15 min. 

The purpose of this step was to obtain Ni+ ions and their homogeneous dispersion in the solution. 

The resulting suspension was transferred to porous indium phosphide. The samples were heated in 

a muffle furnace at 230 °С for 3 hours. Then the samples were cooled to room temperature. 

Following the experiment, the samples were air-dried for 3 months. 

The morphology of the obtained structures was researched using SEO-SEM Inspect S50-B 

scanning electron microscope. The chemical composition was researched by EDX method. The 

calculation by surface points and mapping technology was applied. 

Results and discussion 

Figure 1 shows the morphology of the n-InP porous surface following electrochemical etching. 

Image analysis provides evidence of two types of etching pits, the occurrence of which is conditional 

on two different mechanisms of electrochemical crystal dissolution. 

The first type – massive etched areas that shall be the result of etching at the surface defect 

location areas. The size of such etching pits in the transverse diameter is 5 μm. It can be seen that 

such areas are characterized only by surface etching - etching pits do not advance into the depth of 

the sample, and they grow mainly on the crystal surface. 

 
Figure 1. SEM image of the morphology of por-InP porous surface  

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The second type – so-called ‘seeding pore formation’- is characterized by spontaneous removal 

of atoms from the crystal surface. Such etching may lead to disruption of the stoichiometric 

composition of the material as a result of uneven etching of phosphorus and indium lattices. These 

etching pits form an assembly of small pores on the surface. The average pore diameter varies from 

70 to 200 nm. The pores grow to the deep of the crystal in the form of thin parallel channels. The 

surface porosity is -below 15 %, which characterizes such a structure as a low porosity structure. 

As a result of etching, the sample stoichiometry was significantly disrupted (Figure 2 and Table 1). 

Almost the same concentrations (in atomic units) of indium and phosphorus may be observed. Carbon 

is also on the surface, it appeared due to the interaction of the sample surface with the electrolyte. In 

the etching of semiconductors in acid solution, the interphase layers are formed during constant 

potential superposition at the semiconductor/electrolyte interface (the Gouy-Chapman layer, the 

Helmholtz layer). The result shall also be the formation of adsorbed species, which may subsequently 

form stable compounds. Most likely, the presence of carbon is conditional on this mechanism. 

 
Figure 2. EDX spectrum of por-InP synthesized by electrochemical etching on mono-InP substrate. 

Table 1. Elemental composition of por-InP surface by atomic and mass units 

Element Line type Content, mass% Content, at.% 
P K series 20.37 40.64 
In L series 76.05 40.92 
C K series 3.58 18.44 

Total  100.00 100.00 

 

It should be noted that carbon concentration is quite low (3.58 mass.% and 18.44 at.%, 

respectively). Therefore, it can be assumed that these compounds will not have a critical effect on 

the properties of the resulting structure. On the other hand, in order to overcome this phenomenon 

in the course of electrochemical etching, it is necessary to stir the electrolyte, such stirring will 

prevent the formation of bubbles near the crystal surface and will allow forming of a clean structure 

without impurities. 

Figure 3 shows the crystal surface following precipitation of nickel-containing suspension and 

annealing in a muffle furnace. The formation of a solid thin film with crystallites on the surface may 

be observed. The morphology of the resulting structures demonstrates spherical crystallites of 

different diameters that tend to agglomerate. 



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Figure 3. SEM image of por-InP surface with the nickel-containing surface layer 

Figure 4 shows EDX mapping of the formed structure surface. It can be concluded that the structure 

has atoms of indium, phosphorus, oxygen and nickel on the surface. Chlorine and carbon are also 

present in low concentrations. It can be seen that phosphorus and indium are allocated on the surface 

almost evenly. These elements are not observed only in the points of concentration of crystallites. The 

predominant points of oxygen and nickel concentration are crystallites, but they may be observed on 

the entire surface. Chlorine and carbon are present in small inclusions on the crystal surface. 

 
Figure 4. Energy dispersive X-ray (EDX) mapping analysis of the sample 

Based on the data obtained (Fig. 4), it can be assumed that the structure consists of a dense layer 

of nickel oxalate dihydrate (NiC2O4∙2H2O). Nickel oxalate dihydrate is known to be one of the most 

important precursors for the synthesis of nickel oxide and pure nickel [25]. For this purpose, nickel 

oxalate is calcined and dehydrated, resulting in NiO powder [26]. In our case, we used the 

application of NiC2O4∙2H2O solution on the por-InP substrate, resulting in the formation of oxalate 

containing layer with NiO inclusions (crystallites). Our results are in good agreement with the data 

previously obtained [27,28]. Note that a similar mechanism of synthesis of NiO nanocrystallites with 

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NiC2O4∙2H2O is demonstrated in the paper [28], with the fundamental difference that the oxalate 

layer was transferred to the oxide layer within 24 hours. 

Figure 5 (a - i) demonstrates the crystallites formed on the film surface. It can be seen that the 

crystallites tend to agglomerate (Fig. 5 a, b, f). Some of them have open ‘windows,’ which is evidence 

of the evaporation of water from them in the course of thermal annealing (b, c, d). Crystallites have 

a very large scatter in diameter - from 100 nm to 10 μm. In particular, we can distinguish three 

characteristic dimensions: 

[1] massive crystallites, that are the agglomerates of smaller ones, having a size of 10 - 20 μm (Fig. 

5 b, e, f); 

[2] medium crystallites, the size of which is in the range 1 - 5 μm (Fig. 5 a, d, e); they have a 

characteristic spherical shape or torus shape; 

[3] small crystallites of nanometer size - from 100 to 200 nm (Fig. 5 c, e); such crystallites pack 

densely on the surface, and they are allocated in the form of islands. 

The presence of various types of structures shall be the evidence of evaporation and crystal-

lization process incompleteness. In the event of longer processing periods, the islands will be ‘dried 

out’ and crystallized. This argument is also supported by the fact that the crystallites are in the form 

of nanowires in certain points, it is a characteristic of nickel oxide [29]. Figure 5 (g, h, i) demonstrates 

the wire structures are formed. Their thickness is 0.5 -1 µm, and length 2- 3 µm. 

Thus, a multilayer structure was formed, it contained 4 basic layers (from bottom to top) (Figure 6): 

[1] a layer of monocrystal InP - virgin crystal, basic ‘working’ substrate; 

[2] a porous InP layer that was formed by electrochemical etching on mono-InP in order to make 

the surface rough and to etch defects that are the sources of excessive stress; 

[3] a thin layer of nickel oxalate, NiC2O4∙2H2O, that was formed on the por-InP surface by application 

of the solution and annealing; 

[4] an upper layer consisting of NiO crystallites and nanocrystallites that were formed during partial 

annealing of the nickel oxalate layer. 

 
Figure 5. SEM images of NiO crystallites and nanocrystallites 



Y. Suchikova et al. J. Electrochem. Sci. Eng. 12(4) (2022) 593-601 

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The nickel oxalate layer transformation is evidenced by cracking in some parts of the surface 

(Figure 7). Due to the aqueous phase drying, it can be seen that the layer becomes brittle, cracked 

and separated from the surface of porous indium phosphide in these parts. Such behavior is typical 

and predictable. If annealing is continued for longer, the layer will be separated from the surface. 

The main problem is the preservation of NiO crystallites on the InP surface. The formation of por-

InP on mono-InP allows one to solve this problem partially. 

 
Figure 6. Schematic image of NiO/NiC2O4∙2H2O/por-InP/mono-InP structure 

 
Figure 7. SEM images of NiO/NiC2O4∙2H2O/por-InP/mono-InP structure surface 

As already mentioned, nickel oxide is a very promising material. Thus, NiO nanoparticles are 

widely used as anodes for lithium-ion batteries [30], they are also promising for use in 

electrochemical supercapacitors [31]. Their use as sensitized dyes and as photocathodes have been 

reported [32]. Electrochemical, magnetic and antibacterial properties are also striking [33]. There-

fore, further development of the methods for obtaining nickel oxide nanoparticles is necessary. It 

should be noted that the first steps of the simple synthesis of crystallites and nickel oxide 

nanoparticles on porous semiconductor substrates were made in the presented research. The 

technology requires further improvement, particularly in the removal of the oxalate layer from 

substrate surface and development of mechanisms that will allow the synthesis of more uniform 

particles in size, well adhered to the substrate. 

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Conclusions 

The article demonstrates the simple protocol of synthesis of the NiC2O4∙2H2O layer with NiO 

crystallites. The structures were formed on mono-InP substrate that was pre-etched in order to form 

rough porous layer on the surface. It is demonstrated that the two-stage technology of 

electrochemical etching of the substrate with subsequent application of nickel oxalate on the 

surface and annealing allows the formation of a multilayer structure of NiO/NiC2O4∙2H2O/por-

InP/mono-InP. Provided, however, that NiO is present on the surface in the form of crystallites and 

nanoparticles. Such structure may find striking applications in modern electronic instrumentation. 

Further steps should be taken in order to control the shape and the size of nanostructures, which is 

a common strategy of modern nanophase materials science, and to make decisions on optimization 

of the productivity and efficiency due to structural dependent properties. 

Acknowledgements: Y. Suchikova, S. Kovachov, I. Bohdanov, І. Bardus show their appreciation to the 
Ministry of Education and Science of Ukraine for its support, in particular: grant 0122U000129 
“Search for Optimal Conditions for the Synthesis of Nanostructures on the Surface of Semiconductors 
A3B5, A2B6 and Silicon for Photonics and Solar Energy,” and grant 0121U109426 “Theoretical and 
Methodological Principles of Systemic Fundamentalization of Intended Specialist Training in the Field 
of Nanophase Materials Science for Productive Professional Activity”. 

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@Article{Suchikova2022,
  author    = {Suchikova, Yana and Bohdanov, Ihor and Kovachov, Sergii and Lazarenko, Andriy and Bardus, Iryna and Dauletbekova, Alma and Kenzhina, Inesh and Popov, Anatoli I.},
  journal   = {Journal of Electrochemical Science and Engineering},
  title     = {{The Synthesis of porous indium phosphide with nickel oxide crystallites on the surface:}},
  year      = {2022},
  issn      = {1847-9286},
  month     = {jul},
  number    = {4},
  pages     = {593--601},
  volume    = {12},
  abstract  = {In this paper, the technology of synthesis of crystallites and nanocrystallites of nickel oxide on the surface of indium phosphide is described. This technology consists of two stages. In the first stage, porous indium phosphide is formed on the surface of a single crystal of indium phosphide. The formation of such a porous layer provides better adhesion to the surface of the sample. The second stage involves the preparation of the solution that contains nickel ions, application of this solution to the surface of porous indium phosphide, followed by annealing. As a result, NiO/NiC2O4∙2H2O/por--InP/mono-InP structure was formed. Surface morphological parameters were obtained using scanning electron microscopy and EDX-analysis of chemical composition. Chemical analysis confirmed the partial formation of nickel oxide from nickel oxalate layer by thermal annealing. Using scanning electron microscopy, it has been established that the crystallites have a large scatter in diameter, but they may be divided into three characteristic groups: macro-; meso- and nano­crystallites. Such structures may find prospects for application in electrochemical capacitors and lithium-ion batteries. Further research is needed for methodology improvement to obtain structures with predetermined controlled properties.},
  doi       = {10.5599/JESE.1301},
  file      = {:D\:/OneDrive/Mendeley Desktop/Suchikova et al. - 2022 - The Synthesis of porous indium phosphide with nickel oxide crystallites on the surface.pdf:pdf;:02_jESE_1301.pdf:PDF},
  keywords  = {EDX spectrum, annealing, coating, electrochemical etching, nickel oxalate},
  publisher = {International Association of Physical Chemists (IAPC)},
  url       = {https://pub.iapchem.org/ojs/index.php/JESE/article/view/1301},
}