a 
  

© 2022 Indonesian Society for Science Educator  176 J.Sci.Learn.2022.5(1).176-192 

 

 
Received:  1 June 2021 
Revised: 5 October 2021 
Published: 1 March 2022 

 

 

Analysis of Prospective Primary School Teachers’ Knowledge Regarding 
Chemical Representations on Crystallization Experiment 

Melis Arzu Uyulgan1*, Nalan Akkuzu Güven1 

1Chemistry Education, Mathematics and Science Education Department, Faculty of Education, Dokuz Eylul University, Turkey 
 
*Corresponding author: melisarzucekci@gmail.com 
 

ABSTRACT The study aims to determine the subject matter knowledge of Prospective Primary School Teachers (PPSTs) and 
analyze their chemical representation levels on crystallization. The study was carried out with descriptive research with a qualitative 
approach based on this purpose. The study participants were eighty freshman students studying at the Department of Primary 
Education in a state university in the Aegean Region of Turkey. The data were collected using a worksheet containing seven open-
ended questions regarding the crystallization experiment. The questions were about the solubility of salt in water, the formation of 
the salt water and its solubility-temperature graph, the formation of the saturated salt water, and the appearance of particles formed 
during crystallization. A worksheet was prepared to determine the chemical representation levels of the PPSTs, and the data were 
subjected to document analysis. The researchers conducted a demonstration experiment and an animated video on the extraction of 
table salt by crystallization as an activity during the study process. The results indicated that PPSTs' responses related to crystallization 
were mainly at the macroscopic level. At the same time, they had great difficulty explaining at the levels of sub-microscopic and 
symbolic representations. Moreover, they could not explain the concept of dissolution with scientific expressions and distinguish the 
mixtures from each other. Additionally, most prospective teachers could not draw the correct solubility-temperature graph, so they 
had difficulty in symbolic representations. The study results imply that to raise the quality of science education in Turkey, PPSTs 
must attend a quality teaching of science, so primary school students acquire scientifically accurate knowledge of the basic science 
subjects and concepts such as dissolution, solubility, and crystallization.     

Keywords Chemical Representations, Prospective Primary School Teachers, Crystallization, Science Education 

1. INTRODUCTION 
The primary education period is the first step where 

basic education starts, and students acquire various skills, 
behaviors, and attitudes. Among the main goals of this step 
is to deliver quality science education. Science is one of the 
most important fields that uses observation and 
experimentation to describe and explain natural 
phenomena. As can be understood, science has a structure 
that gives more information about the state of things in 
macroscopic structures. On the other hand, science 
learning involves observing various natural phenomena 
and understanding how natural phenomena exist or occur 
(Merino & Sanmarti, 2008). Thus science courses also 
challenge teaching students about phenomena that humans 
often cannot directly interact with. In this case, it becomes 
difficult to understand due to its complex structure. 
Therefore, it is extremely crucial to employ representations 
to realize meaningful learning (Johnstone, 2010; Lindawati, 
Wardani, & Sumarti, 2019). 

When looked at from the point of science, 
representations have played an essential role in 
constructing science knowledge because representations 
convey knowledge many times about objects which 
humans cannot directly interact with or quickly summarize 
(Polifka, 2021). Conveying information helps support 
science processes, including learning (Wu & Puntambekar, 
2012) and communication (Kozma, 2003). Students can 
develop better scientific understanding by engaging in the 
construction of representation. Representations are 
essential, especially for students to efficiently learn the 
basic abstract concepts in scientific fields, differentiate 
observable and invisible phenomena, and experience 
correct and meaningful learning in their minds. Suppose we 
recognize the acts of thinking and interrogating each as a 
building block of meaningfulness (Aubrey, Ghent, & 

mailto:melisarzucekci@gmail.com


Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  177 J.Sci.Learn.2022.5(1).176-192 
  

Kanira, 2012). Quality science education can offer students 
various mental processes to acquire higher cognitive skills 
and representations. At this point, it is highly crucial to use 
dynamic analogies (Hermita et al., 2020), activities such as 
experiments, animations, educational videos (Akkuzu 
Güven & Uyulgan, 2021), and online activities (Polifka, 
2021) to reveal representations and to provide meaningful 
learning. According to recent studies, these activities help 
students observe, investigate, and understand the physical 
world through direct experiences with the phenomena or 
manipulating objects and materials (Akkuzu Güven & 
Uyulgan, 2021; Banawi, Sopandi, Kadarohman, & 
Solehuddin, 2019). 

Moreover, primary school teachers are the most 
important actors who guide science education to ensure 
that students possess all these acquirements by performing 
the activities and are raised by the intended goals. The 
system's success is directly related to teachers' achievement 
(Knowles, Holton, & Swanson, 2005). Therefore, it is 
critically important that primary school teachers, and 
indeed, prospective primary school teachers (PPSTs) have 
advanced competency in science teaching to ensure a 
quality process of science learning. Many studies emphasize 
that this level of education plays a crucial role in raising 
individuals interested in and exhibiting positive attitudes 
towards science (Duschl, Schweingruber, & Shouse, 2007; 
Pine, Messer, & St. John, 2001; Uludüz, 2017). Because the 
theory of particles is a foundation of the mindset in science 
education that starts from primary school (Treagust et al., 
2010), understanding the microscopic world and 
establishing its relationship with other representations is 
essential for meaningful learning to occur. From this point 
forth, the present study focuses on PPSTs' subject matter 
knowledge in terms of macroscopic, sub-microscopic, and 
symbolic levels of chemical representations using 
demonstration experiments and animated video. 
Specifically, educators need to identify PPSTs' basic 
chemistry knowledge through chemical representations. 
When they start their professional life, they are the only 
experts who will teach students with in-depth knowledge 
of the subjects, not superficial, by using various chemical 
representations. They have a big part in making science 
courses more real. 

In their future professional lives, prospective teachers 
cannot be expected to teach their students the knowledge 
and skills that they do not readily have. It is also necessary 
that they transfer them through practical and meaningful 
ways. It is therefore crucial that prospective teachers do not 
have misconceptions and inadequate or inaccurate 
knowledge of their subject matter (Härmälä-Braskén, 
Hemmi, & Kurtén, 2020). Primary school teachers 
administer basic science education starting from the 3rd and 
4th years of primary school. Furthermore, it requires PPSTs 
to be trained in a way that equips them with the necessary 
subject matter knowledge related to basic science concepts 

(Knowles et al., 2005). It is reported that prospective 
teachers have inadequate or incorrect knowledge of science 
concepts in the studies covering the northern part of 
Turkey (Demircioğlu, Demircioğlu, & Ayas, 2004) and the 
south-eastern part of the USA (Schulte, 2001). An 
established finding is that these prospective teachers 
graduate in an incompetent state of misconceptions and 
incorrect knowledge of science concepts, resulting in their 
students carrying similar misconceptions in science 
(Lemma, 2013). A teacher who is competently 
knowledgeable in the subject matter will undoubtedly tend 
to be more self-confident, devoted, and conscious about 
what and how to teach. Therefore, among the essential 
characteristics expected of teachers is to possess substantial 
subject matter knowledge (Aydeniz, Bilican, & Kirbulut, 
2017). The initially-acquired knowledge and affective 
behaviors of science could be had at the early years' stage 
(Dusch et al., 2007). In this respect, primary school 
teachers have an essential responsibility. Studies reported 
that science was one of the least taught subjects at the 
primary school level. Primary prospective school teachers 
had mainly negative beliefs about science teaching and had 
less efficacy for teaching science than for other subjects in 
the primary curriculum (Buss, 2010; Petersen & Treagust, 
2014).  

Considering this situation, primary school teachers 
must be competent in science concepts and ensure that 
their students acquire this knowledge in a laboratory 
environment (Kurt & Birinci Konur, 2017). Herga, Čagran, 
and Dinevski (2016) suggested that laboratory work is the 
most effective primary method when acquiring science 
knowledge. Practical work provides students with cognitive 
processes such as concretizing abstract concepts, problem-
solving, analyzing, critical thinking, synthesizing, 
evaluating, decision making, and creativity (Kurt & Birinci 
Konur, 2017). According to the current four-year 
undergraduate curriculum of universities in Turkey, PPSTs 
are trained about the main concepts of science and science 
teaching during the courses Basic Science in Elementary 
School and Teaching Science. Moreover, through the 
course Laboratory Applications in Science, they become 
competent at various science experiments to acquire the 
skill to design experiments suitable for all grades of primary 
education (Council of Higher Education [CoHE], 2018). 
However, since they do not have the option to pick among 
various subject matters for practicing during Practice in 
Teaching, they graduate with less experience and poor 
comprehension in teaching science compared to other 
subject matters of teaching (Mansfield & Woods-
McConney, 2012). The current study includes PPSTs who 
conducted an experiment on crystallization, a physical 
purification technique in science and is intended to ensure 
that the participants gain experience for correct and 
meaningful learning. It is believed that the study might also 



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  178 J.Sci.Learn.2022.5(1).176-192 
  

help identify the aspects where the prospective teachers are 
incompetent in crystallization.  

It is known that chemistry is the field where students 
experience comprehension problems the most. It is mainly 
because most concepts are abstract, and an unfamiliar 
language is used in chemistry (Barak & Dori, 2004; Eilks & 
Hofstein, 2015). The concern among science educators 
about when is the most appropriate time to introduce the 
concept of particles involving atoms and molecules in the 
science curriculum is the primary school level (Johnstone, 
2010; Tsaparlis, Kolioulis, & Pappa, 2010). Tsaparlis et al. 
(2010) have suggested delaying the introduction of the 
concepts of atoms and molecules until such time when 
students are ready to assimilate these ideas into their 
cognitive structures.  When primary school students have 
misconstruction of the basic chemistry concepts such as 
atom and molecule, they subsequently experience 
difficulties in comprehending advanced concepts and 
associating them with the knowledge they were taught 
previously (Canpolat & Pınarbaşı, 2012). 

Additionally, PPSTs have difficulty understanding 
chemistry because it requires them to transfer between 
macro (observable, concrete), sub-microscopic (invisible, 
abstract), and symbolic levels of reaction (Derman & 
Ebenezer, 2020; Johnstone, 2000). The macro is what can 
be explained by sense organs; the sub-microscopic is the 
cognitive model of the matter which is used to explain or 
predict the properties of substances; and the symbolic is 
the representation of the macro and sub-microscopic area 
with symbols (Ye, Lu, & Bi, 2019). Head, Yoder, Genton, 
and Sumperl (2017) emphasized that in the absence of a 
chemical representation, pre-service teachers experience 
difficulty constructing an accurate mental model or internal 
representation based solely on a text description of abstract 
chemical concepts. 

Johnstone (2000) uses a Chemistry Triangle to 
symbolize these representations that facilitate 
comprehension of chemistry knowledge. Johnstone also 
noted that students' correct comprehension of chemistry 
concepts occurs within the triangle, not at just one apex of 
the triangle or along one edge of the triangle. Underlining 
that expert teachers achieve it as they move fluently across 
this triad from one representational domain to another, 
Johnstone recommends that teachers plan to teach 
students chemical representations by bridging and seeing 
the connections between the different domains of chemical 
representations. Juriševič, Glažar, Razdevšek Pučko, and 
Devetak (2008) reported that a reasonable understanding 
could be established when all three levels of the concept 
describe each other in a specific way in students' working 
memory. It is, therefore, necessary that teachers are aware 
of the connections between each domain. This cognition 
will enable the students to construct an appropriate internal 
representation and connect among these three levels, 
helping them learn chemical concepts easily. 

Recent studies show that primary teachers and teacher 
candidates have considerable difficulties in understanding 
the basic science and chemistry concepts, such concepts as 
chemical and physical changes, dissolution, heterogeneous 
mixture, and homogenous mixture (Akkuzu Güven & 
Uyulgan, 2021; Aydeniz, Bilican, & Kirbulut, 2017; 
Derman & Ebenezer, 2020; Håland, 2010; Härmälä-
Braskén et al., 2020; Hermita et al., 2020; Lemma, 2013; 
Nandiyanto et al., 2018; Sopandi, Kadarohman, Rosbiono, 
Latip, & Sukardi, 2018; Yerrick & Simons, 2017). 
Therefore, more studies are needed to explain their 
chemical knowledge in great detail. This study seeks to 
determine the PPSTs' subject matter knowledge related to 
crystallization and analyze their chemical representation 
levels (macroscopic, sub-microscopic, and symbolic levels) 
on crystallization.   
 
2. METHOD 

2.1. Research Design 
This research is a descriptive study with a qualitative 

approach. Descriptive research describes the existing 
situation using scientific procedures to answer real 
problems. Descriptive data are produced in written or oral 
words of observed behavior, activities, features, changes, 
relationships, similarities, and differences between one 
phenomenon and another. In this type of research, the 
understanding and meaning of individuals and groups are 
tried to be described (Creswell, 2012). As this study is 
descriptive research, it aims to determine and describe the 
macroscopic, sub-microscopic, and symbolic 
representation levels of the PPSTs related to the science 
subject of crystallization, which is one of the methods of 
separating mixtures. This study is an investigation designed 
to provide baseline information that will aid and facilitate 
the development of other complex study strategies. 
2.2. Participants 

The current study participants consisted of first-year 
students studying at the Department of Primary Education 
in a state university located in the Aegean Region of 
Turkey. Participants were selected based on the purposive 
sampling method that could be very useful when the 
researcher needs to reach a targeted sample quickly 
(Creswell, 2012). Due to the limitations in terms of time 
and labor, this sample is chosen from easily accessible 
(Yıldırım & Şimşek, 2013). In addition to this choice, the 
PPSTs have quite similar backgrounds, such as 
socioeconomic status and grade level. Although they took 
general chemistry lessons in the first year of high school, 
they did not take any chemistry or science lessons in the 
following terms. Therefore, their background concerning 
science subjects is approximately the same. A total of 80 
PPSTs have voluntarily participated in the study. 46 of 
them were women (57.5%), whereas 34 were men (42.5%). 
Data were collected within a 2-hour practice in the General 
Chemistry course taught in the 2018 spring semester. In 



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  179 J.Sci.Learn.2022.5(1).176-192 
  

order to have the study conform to ethical considerations, 
all of the prospective teachers were informed about the 
purpose and process of the research. 
2.3. Data Collection 

The data in the study were obtained through the use of 
worksheets developed by the researchers. A worksheet on 
the crystallization experiment was prepared to determine 
the macroscopic, sub-microscopic, and symbolic 
representation levels of the PPSTs. Worksheets are written 
documents containing the process of the activities 
participants will do in a particular order. These documents 
ensure the participation of the whole class in the given 
activity simultaneously. The worksheet consisted of 7 
open-ended questions regarding the experiment of 
crystallization. The questions were about the solubility of 
salt in water, the formation of the salt water and its 
solubility-temperature graph, the formation of the 
saturated salt water, and the appearance of particles formed 
during crystallization. PPSTs were asked questions about 

each representation in open-ended questions, and PPSTs 
were also asked to draw. Two experts from the 
Mathematics and Science Education department evaluated 
the questions for validity and reliability. The final versions 
of the questions examined within the scope of the research 
are included in the results section. 
2.4. Validity and Reliability of Data Collection Tool 

In order to provide the validity of the data collection 
tool, the worksheet questions were evaluated by two 
experts in terms of content, language, and 
comprehensibility. The experts scored the questions 
according to the specified degrees adequate (3), adequate 
but correction required (2), and not enough (1) (see Table 
1).  

In order to establish the reliability of the study, the 
worksheets were analyzed and scored by two researchers 
independently at different times. The reliability formula of 
Miles and Huberman (Reliability = 

Agreement/[Agreement+Disagreement] × 100) was 
applied to each question of the worksheet form. The 
agreement percentage representing interrater reliability 
among researchers was determined as 96%, indicating that 
the coding was reliable and the coherence excellent (Miles 
& Huberman, 1994). 
2.5. Procedure 

During the data collection process, worksheets related 
to the crystallization experiment of impure salt were 
distributed to the PPSTs. The researchers conducted a 
demonstration experiment on the extraction of table salt by 
crystallization as an activity for the PPSTs in the classroom 
environment. Immediately after the experiment, an 
animated experiment video on the preparation of table salt 
was shown (see Table 2). The experiment video was chosen 
according to the level of the PPSTs. In the meantime, they 
were asked to answer the macroscopic, sub-microscopic, 
and symbolic questions on the worksheet according to the 
flow of the experiment. 

 

Table 1 Evaluation criteria for worksheet’s validity 

Expert 1 Expert 2 

 
 
Total 

Q
u
e
st

io
n

 n
u
m

b
e
r 

C
o

n
te

n
t 

L
an

g
u
ag

e
 

C
o

m
p

re
h

e
n

si
b

il
it

y
 

C
o

n
te

n
t 

L
an

g
u
ag

e
 

C
o

m
p

re
h

e
n

si
b

il
it

y
 

1 3 3 3 3 3 2 17 
2 3 2 3 3 3 3 17 
3 3 3 3 3 3 3 18 
4 3 3 3 3 3 3 18 
5 3 3 2 3 3 3 17 
6 3 3 3 3 3 3 18 
7 3 3 3 3 3 3 18 

 

Table 2 The stages of demonstration experiment and animated video experiment 

Stages Demonstration experiment Animated video experiment 

1 15 g of impure table salt is weighed and placed in a 
beaker containing 50 mL of distilled water. 

Some water is taken in a container and heated. 

2 The mixture in the beaker is heated up to the boiling 
temperature. 

When water (solvent) starts boiling, some table salt is 
added slowly.   

3 The saturated hot solution is filtered into an 
Erlenmeyer flask using filter paper and glass funnel 
and thus separated from water-insoluble impurities. 

The mixture is constantly stirred, and salt is added 
until more salt dissolves in water. 

4 The saturated sodium chloride (NaCl) solution is 
allowed to cool down at room temperature. Then, 
the solution is left to crystallize. 

The saturated solution is filtered into an Erlenmeyer 
flask using filter paper and a glass funnel. Then, it is 
allowed to cool down.  

5 At the end of crystallization, the crystals formed are 
washed with pure water. 

A stick is taken, and the string is tied to the stick. 
Finally, the string is placed inside the solution.  

6 The crystals formed are filtered and dried in the air. After a while, large salt crystals suspended are 
observed to form on the string.  

 



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  180 J.Sci.Learn.2022.5(1).176-192 
  

 
2.6. Data Analysis 

Documents enable uncovering meaning, developing 
understanding, and discovering insights relevant to the 
research problem (Merriam, 1988). Since the worksheet 
was used as a document in this study, the data were 
subjected to document analysis. According to this 
approach, the content of written documents is analyzed 
systematically (Wach & Ward, 2013). For this purpose, the 
answers of the PPSTs were firstly examined under chemical 
representation levels. In order to determine these levels of 
the PPSTs, the categories were identified in line with their 
direct statements. For some questions (1, 2, 3, 6a), written 
responses and drawings were coded according to four 
categories that were correct, partially correct, incorrect and 
no answer (N/A) in line with specific criteria (Coştu, Ayas, 
Çalık, Ünal, & Karataş, 2005). Meanwhile, the answers to 
the graphic drawing in the 4th, 5th, and b part of the 6th 
questions were categorized as correct, partially correct, and 
incorrect drawing. "Correct" responses correspond to the 
PPSTs' answers that match the scientific knowledge, 
"partially correct" responses include PPSTs' answers that 
overlap with scientific knowledge but contain missing 
information about the question. "Incorrect" responses 

include answers that do not correspond to scientific 
knowledge, and "N/A" means that are not answered or 
whose responses are meaningless. From the written 
statements of the PPSTs, not only was it possible to find 
how they formed associations for the chemical 
representations, it was possible to discover where they had 
difficulties related to chemical representations on 
crystallization. Responses in terms of accuracy categories 
were analyzed descriptively by frequencies and percentages 
regarding the number of PPSTs. Also, the analyses 
concerning the chemical representations were done 
according to frequencies within the PPSTs' responses. The 
frequency numbers were the number of repetitions of the 
statements of PPSTs. Therefore, the total of the 
frequencies was not equal to the total number of 
participants (N = 80). More or fewer frequencies than the 
number of participants would be seen in the presented 
findings tables. Figure 1 shows a step-by-step summary of 
how to analyze the worksheet. 
 
3. RESULTS AND DISCUSSION 

In the light of research questions, the PPSTs' responses 
were first categorized as correct, partially correct, incorrect, 
and N/A; then, their analyses results were assessed by 

 
Figure 1 Step-by-step worksheet analysis 

 

 
Figure 2 PPSTs’ responses to the first question presented with their frequency and percentage distribution by categories 

 

f = 65 (81%)

f = 14 (18%) f = 1 (1%)

Correct response

Partially correct response

Incorrect response



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  181 J.Sci.Learn.2022.5(1).176-192 
  

levels of chemical representations. Finally, the results of 
their frequency and percentage distribution values were 
presented descriptively in the following graphs.  

The PPSTs were asked the first question, i.e., "How is 
salt obtained?" and instructed to make necessary 
explanations. As seen in Figure 2, most of them (81%) 
responded with correct answers; the rests were 18% 
partially correct and 1% incorrect. From the analysis results 
in Table 3, according to the levels of chemical 
representation, we found that the PPSTs had mostly 
macroscopic-level statements (f = 70). Table 3 shows the 
chemical representation levels of the PPSTs' responses to 
this question, along with the relevant sample statements. 
Among the correct answers given by the PPSTs were 
evaporating seawater and crystallization, while some of 
their partially-correct statements also included simple 
distillation. The first statement that came to the mind of 
the PPSTs in their responses to how salt was obtained was 
the method of evaporation of seawater. Crystallization is 
ranked second among their responses. This result indicates 
that the prospective teachers only have a casual knowledge 
of the subject, and they were inadequate to think of 
practical procedures in terms of chemistry teaching. 
Laboratory practices are the applications that enable the 
concretization of abstract concepts. They also allow 
prospective teachers to discover the associations between 
the three levels of chemical representations, thereby 
facilitating better learning. This result is consistent with the 
study of Kelly, Akaygün, Hansen, and Villalta-Cerdas 

(2017), who reported that laboratory experiments could 
support students' thinking skills. Through these 
experiments, the students can connect the macro and 
micro levels of an abstract science concept. Sanchez (2021) 
also pointed out that implementing strategies such as an 
experiment-oriented approach can lead a better 
understanding of the topics as the students visualize the 
given phenomena.  As well as macroscopic level 
statements, there were some noteworthy answers given at 
sub-microscopic (f = 11) and symbolic (f = 2) levels (see 
Table 2). The sub-microscopic statements explained that 
salt is obtained through ionic bonding and with the sodium 
and chlorine atoms compounding. At the same time, their 
answers of symbolic level referred to the reaction equation 
of sodium and chloride ions. The answers of these levels 
revealed that most PPSTs gave the compound of NaCl as 
an example to refer to salt, which suggests that they 
perceive salt to be a compound of sodium and chlorine 
ions.  

The second question was intended to investigate how 
the PPSTs identify crystallization used to purify solids and 
is one of the production and purification techniques used, 
especially for saturated salt solutions. As shown in Figure 
3, 36% of the PPSTs responded with scientifically correct 
answers, 40% partially-correct answers, and 16% incorrect 
answers, and 8% of them had N/A. To consider the 
analysis results in terms of representation levels, we found 
that all of the relevant statements were at the macroscopic 
level (see Table 4). The analysis results in Table 4 revealed 

Table 3 The results of the analysis of the PPSTS’ responses to the first question 

Representation 
Levels 

Statements Frequency values of the 
statements 

Macroscopic Obtained by evaporating and purifying seawater.  49 

Obtained by crystallizing.  12 

Obtained through simple distillation.  7 

Obtained by grinding rock salt.  2 

Total  70 

Sub-microscopic Obtained through ionic bonding.   
Obtained with the sodium and chlorine atoms compounding.  

11 

Total  11 

Symbolic Obtained using the equation Na+ + Cl-→NaCl 2 

Total  2 

 

 
Figure 3 PPSTs’ responses to the second question presented with their frequency and percentage distribution by 
categories 

 

f = 29 (36%)

f = 32 (40%)

f = 13(16%)

f = 6 (8%)

Correct response

Partially correct response

Incorrect response

N/A



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  182 J.Sci.Learn.2022.5(1).176-192 
  

that most PPSTs described crystallization as the technique 
where water is evaporated (f = 18). This finding might be 
due to the PPSTs’ thoughts that water in salt-water mixture 
vanishes through evaporation. Similar to this finding, some 
PPSTs (f = 10) described crystallization as the method used 
to separate liquids from solids through evaporation. These 
findings indicate that the PPSTs confuse crystallization 
with evaporation. In response to the second question 
where we expected them to explain crystallization, the 
PPSTs answered most, stating that it is water evaporation. 
This result also shows that the prospective teachers had 
inadequate knowledge about crystallization, which is one of 
the separation methods and mostly confused it with the 
evaporation method. In parallel to this result, Coştu, Ayas, 
Açıkkar, and Çalık (2007) reported that in response to an 
open-ended question asking students how they would 
separate a solid matter dissolved in a solvent from the 
solvent, majority of the students referred to evaporation as 
the separation method they would use.  We also found out 
that some PPSTs described crystallization as a technique 
used to separate solid-liquid mixtures, which concluded 
that the PPSTs had inadequate knowledge about the 
technique (f = 16). Only a few of the PPSTs’ responses 
contained correct information about crystallization (f = 9), 
while there were also many incorrect answers describing it 
as the phase transition from gas to solid (f = 4) and the 
phase transition of a dissolved liquid to solid through 

crystallizing (f = 4). This finding points out that the PPSTs 
cannot associate crystallization and solubility. The purpose 
of the crystallization experiment is to explain how the 
solubility of a solid matter changes depending on the 
temperature while it is being purified. Therefore, the 
prospective teachers are required to be knowledgeable 
about solubility, the phenomenon of dissolving, and the 
factors affecting solubility. Our results, however, found out 
that they had incorrect knowledge about the concept of 
dissolution. Following this result, Taylor and Coll (2002) 
revealed that pre-service primary teachers could not explain 
the concept of dissolution with scientific expressions, and 
they reported that only one of them could explain 
dissolving in terms of attraction and bonding between 
molecules. Akkuzu Güven and Uyulgan (2021) stated that 
the lack of understanding of the prospective primary 
school teachers in the concepts of mixtures and dissolution 
might also be due to their insufficient laboratory 
experience.  

We also determined that the prospective teachers could 
only give mostly macroscopic answers to the questions. 
Likewise, Derman and Ebenezer (2020) reported that the 
prospective primary teachers knew physical and chemical 
changes mainly composed of macroscopic concepts. 
Moreover, they also revealed the need for the sub-
microscopic and symbolic knowledge representations 

Table 4 The results of the analysis of the PPSTS’ responses to the second question 
Representation 

Levels 
Statements Frequency values of 

the statements 

Macroscopic It is the evaporation of water.  18 

It is a technique used to distill solid-liquid mixtures. 16 

It is a technique of separating the liquid from the solids through 
evaporation.  

10 

It is to purify solid matters.  9 

It is the extraction of substances like salt and sugar.  6 

It is the transformation of a dissolved liquid into a solid by 
crystallizing. 

5 

It is to freeze and reheat a mixture.  4 

It is the transition phase from gas to solid.  4 

It is a separation technique by using the difference in solubility. 2 

Total  74 

 
 

 
Figure 4 PPSTs' responses to question 3a presented with their frequency and percentage distribution by categories  

 

f = 25 (31%)

f = 15 (19%)

f = 38 (47%)

f = 2 (3%)

Correct response

Partially correct response

Incorrect response

N/A



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  183 J.Sci.Learn.2022.5(1).176-192 
  

connected with the missing steps of the instructional 
design. 

The third question on the worksheet is composed of 
three parts of 3a, 3b, and 3c. In the macroscopic question 
3a, the PPSTs were asked what they would observe when 
adding salt into the water in a beaker. Unfortunately, 47% 
of them had incorrect answers, while only 31% had correct 
answers; additionally, 19% had partially correct answers; 
and 3% had N/A (see Figure 4). This is because the PPSTs 
answered this macroscopic question at sub-microscopic 
and symbolic levels and were unable to differentiate 
homogeneous and heterogeneous mixtures.   

The results presented in Table 5, considering the 
PPSTs' chemical representation levels, show that they had 
responses about other representations while expecting 
macroscopic answers. This might be because they could 
not comprehend the differences between representation 
levels soundly. Among the incorrect answers, some PPSTs 
stated that salt sinks to the beaker's bottom (f = 39), they 
form a heterogeneous mixture (f = 7), and salt particles stay 
visible in the beaker (f = 3). These findings are linked with 
the inadequate knowledge that the PPSTs have about the 

term “dissolution”. Our results also demonstrated that the 
prospective teachers frequently used macroscopic 
statements such as disappearing and becoming particles 
invisible to the naked eye while addressing the salt 
dissolving in water. Studies' results are consistent with this 
result report that both students and prospective teachers 
defined the concept of dissolution as the disappearance of 
the dissolving substance (Demirbaş, Tanrıverdi, Altınışık, 
& Şahintürk, 2011; Kabapınar, Leach, & Scott, 2004; 
Tarkın Çelikkıran & Gökçe, 2019). Ye et al. (2019) maintain 
that due to the abstract idea of the charge of the ions, 
students cannot ''see'' at the microscopic level.  

The answers given by the PPSTs to question 3b, "What 
happens when you heat salt-water mixture?" are shown in 
Figure 5. The majority of the PPSTs (41%) had incorrect 
answers. Table 6 shows that the explanations of the PPSTs 
were at macroscopic and sub-microscopic levels. These 
statements at the macroscopic level included that salt 
dissolves in water and becomes invisible (f = 24). The 
previously heterogeneous mixture becomes a 
homogeneous mixture (f = 4). Although their statements 
are observed to pertain to the macroscopic level, it is also 

Table 5 The results of the analysis of the PPSTS' responses to question 3a  

Representation 
Levels 

Statements Frequency values of the 
statements 

Macroscopic Salt sinks to the bottom. 39 

They form a homogeneous mixture.  21 

They form a heterogeneous mixture.  7 

Salt dissolves in the water and becomes invisible. 7 

Salt becomes visible, and water blurs. 3 

Total  77 

Sub-microscopic Salt particles stick to each other and float in the water.  6 

Particles of water and salt are equally dispersed as the solution is 
homogeneous.  

3 

Compared to particles of water, salt particles stay closer to each other.  2 

Salt appears to adhere to water molecules as it is a homogeneous 
mixture. 

3 

Sodium gives 1 electron to chlorine to form an ionic bond. 2 

Total  16 

Symbolic Salt → NaCl  

Water → H2O  

2 

Total  2 

 

 
Figure 5 PPSTs' responses to question 3b presented with their frequency and percentage distribution by categories 

 

f = 27 (34%)

f = 20 (25%)

f = 33 (41%)

Correct response

Partially correct response

Incorrect response



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  184 J.Sci.Learn.2022.5(1).176-192 
  

understood that they have misunderstandings in terms of 
scientific accuracy. Because they thought that salt dissolves 
only when heated. Some PPSTs also expressed that water 
evaporates and salt sinks to the bottom after the heating (f 
= 19). As the answers given by the PPSTs at the sub-
microscopic level were examined, the statements pertained 
to the particulate level. Although the overall number of 
PPSTs with correct answers at this level was high, others 
still had incorrect answers stating that salt particles move 
closer to each other to have an ordered pattern only when 
heated as salt is solid (f = 5).  

The PPSTs were asked question 3c, "What is the 
purpose of heating the salt-water mixture?" as part of the 
crystallization experiment. Only a few of them (15%) had 
scientifically correct answers to the question, while most 
(54%) of them had partially-correct answers, 26% had 
incorrect answers, and the rest (5%) had N/A (see Figure 
6).  The PPSTs answered this question at macroscopic and 
sub-microscopic levels according to chemical 
representations. Although their statements matched the 
representation levels, there were also scientifically incorrect 
answers. As in the second question, the PPSTs confused 
evaporation with crystallization in this question as well (f = 
22) (see Table 7). Moreover, the PPSTs who stated heating 
is necessary due to the difference in solubility (f = 12) failed 

to comprehend that multiple solid substances dissolve in a 
solvent. Many PPSTs confused melting with dissolving (f 
= 15). There were, however, some other scientifically 
correct answers stating that heating is necessary to 
accelerate the dissolving process (f = 6) and to increase the 
amount of salt dissolving in water (f = 10). There were also 
sub-microscopic answers stating that heat is needed to 
allow particles of salt and water to make a reaction (f = 4). 
This situation reveals that the PPSTs consider dissolving as 
a chemical phenomenon. 

In response to the question on the salt-water mixture, 
some of the prospective teachers described the mixture as 
a heterogeneous mixture, and they did not consider the 
ionic dissolving of salt in their sub-microscopic drawing. 
The prospective teachers could also not demonstrate the 
salt ions being surrounded by water molecules while 
dissolving in their statements and drawings. This result is 
compatible with the study by Tarkın Çelikkıran and Gökçe 
(2019), they determined that although prospective 
chemistry teachers were able to draw a salt consisting of an 
anionic assembly of cations, anions and water molecules, 
they could not illustrate the ions being surrounded by water 
molecules. A similar result is also encountered in the study 
where Uluçınar Sağır, Tekin and Karamustafaoğlu (2012) 
included PPSTs. The study concluded that the prospective 

Table 6 The results of the analysis of the PPSTS’ responses to the question 3b 

Representation 
Levels 

Statements Frequency values of the 
statements 

Macroscopic Salt begins to dissolve in the water and becomes invisible.  24 

Water evaporates, and salt sinks to the bottom.  19 

The previously heterogeneous mixture converts into a homogeneous 
mixture.  

4 

Salt melts in the water.  4 

Salt becomes invisible but keeps its taste.  3 

Total  54 

Sub-microscopic The distance between particles is increased. 15 

Water particles slowly drift apart while salt particles get closer because 
the solids convert into a regular pattern's solid state of matter.   

5 

Kinetic energy and, therefore, the movement of particles increase 
when the temperature rises. 

2 

Salt particles ionize.  2 

Total  24 

 

 
Figure 6 PPSTs' responses to question 3c presented with their frequency and percentage distribution by categories 

 

f = 12 (15%)

f = 43 (54%)

f = 21 (26%)

f = 4 (5%)

Correct response

Partially correct response

Incorrect response

N/A



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  185 J.Sci.Learn.2022.5(1).176-192 
  

teachers had difficulty drawing the phenomenon of salt 
dissolving in water at the particulate level and determining 
which of the various mixtures were solutions. Another 
remarkable result is encountered in the statements of the 
PPSTs referring that salt and water particles make a 
reaction when the salt-water solution is heated. The reason 
why they comprehend the phenomenon of dissolution as a 
chemical fact might be that they could not observe it at the 
sub-microscopic level (Okumuş, Öztürk, Doymuş, & 
Alyar, 2014). 

In the fourth question, the PPSTs were asked to draw a 
solubility-temperature graph to represent the solubility of 
NaCl in water and to explain the reasoning of their 
drawings. This question was mainly intended to understand 
how correctly they could concretize the phenomenon of 
the salt dissolving in water, which is one of the crystallizing 
processes, using a graph at the symbolic level. Most PPSTs 
(75%) had incorrect drawings, while 20% had partially 
correct and 5% had correct drawings (see Figure 7). Some 
of the PPSTs with incorrect drawings (f = 35) assume that 
the salt-water solution is pure. Therefore, they confused 
the solubility-temperature graph with the temperature-time 
graph. Another reason PPSTs had great difficulty drawing 
the graph was that they could not think that the solubility-
temperature curve continued to increase (f = 10). This 
indicates that they confuse evaporation with boiling. 

Finally, some PPSTs (f = 12) explained the saturated salt-
water solution by rote based on the temperature-time 
graph. Despite being correct in the case of the temperature-
time graph, these explanations were scientifically incorrect 
for the question asked about the solubility-temperature 
graph. 

The PPSTs with the partially correct drawing could 
establish that NaCl had a solubility that increased as the 
temperature increased. However, they took 0 oC as the 
initial point where solubility presents (f = 12). Their 
statements also revealed that they had miscomprehension 
about the solubility of salt being directly proportional to 
temperature (f = 4). Moreover, some PPSTs (f = 8) had the 
misunderstanding that salts with solubility, which increases 
as temperature rises, dissolve in water only to an extent (see 
Table 8). Therefore, most prospective teachers could not 
draw the correct solubility-temperature graph for the salt-
water solution. This also indicated that the prospective 
teachers had difficulty in symbolic representations. This is 
because the prospective teachers were unable to distinguish 
between pure substances and solutions and had inadequate 
knowledge about the solubility-temperature graph of the 
solids whose solubility increases with an increase in 
temperature. However, graphs are indispensable 
components of scientific statements (Glazer, 2011). 
Therefore, symbolic representations such as graphs, tables, 

Table 7 The results of the analysis of the PPSTS’ responses to the question 3b 

Representation 
Levels 

Statements Frequency values of the 
statements 

Macroscopic The solution is heated to separate salt from water until the water 
evaporates. 

22 

Salt melts in the water.  15 

We can separate them as they have different solubility values.  12 

Heat facilitates the dissolution of salt in water.  8 

Heat accelerates dissolution. 6 

The amount of salt dissolving in water increases as the solution is 
heated.  

10 

Total  73 

Sub-microscopic Heat allows particles of salt and water to make a reaction. 4 

It is needed for ionization so that salt dissolves in water. 3 

Total  7 

 

  
 

Incorrect drawing Partially correct drawing Correct drawing 

Figure 7 Examples of the graphs drawn by the PPSTs in response to the fourth question 
 



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  186 J.Sci.Learn.2022.5(1).176-192 
  

formulas, equations, etc., are crucial for understanding the 
relations between many science concepts and phenomena 
(Tepe & Akkuzu Güven, 2020; Taber, 2009). Similar to our 
results, Gheith and Aljaberi (2015) found that the pre-
service classroom teachers had poor graph skills, which is 
one of the symbolic representations. Therefore, we can 
conclude that the symbolic level representations provide 
clues that indicate how accurately a science subject has 
been learned. 

In the fifth question, the PPSTs were asked to explain 
what changes happen in a mixture when the amount of salt 
is increased at a specific temperature and to draw an 

appearance of the particles of the mixture.  Most of them 
(67.5%) had incorrect drawings in response to this question 
(see Figure 8). There were only a small number of PPSTs 
with correct drawing (6%), in addition to some others with 
no drawing at all (7.5%). For example, some of them with 
incorrect drawings referred to NaCl using its molecular 
formula at the symbolic level. In contrast, those with 
partially-correct drawings drew at the sub-microscopic 
level but could not demonstrate the ions of salt and water 
compounds to be dispersed (see Figure 9). This finding 
reveals that the PPSTs cannot consider particle size and 
cannot comprehend the dissolution phenomenon. From 

Table 8 The Results of the analysis of the PPSTs' drawings of solubility-temperature graphs about the solubility of NaCl 
in water  

Levels f and % 
values 

Statements Frequency values of 
the statements 

Correct 
drawing 

4 (5%) Solubility increases as temperature rises. 3 
Solubility changes as the saline solution is a homogeneous mixture, 
but not much.  

1 

Partially 
correct 
drawing 

16 
(20%) 

There is a maximum amount of substance that water can dissolve. 
After a while, no matter how much we increase the temperature, the 
solubility terminates at some point. 

8 

The solubility of the salt in water changes directly proportional to 
temperature. 

8 

Incorrect 
drawing 

60 
(75%) 

Water boils at 100 oC and then stays constant.  35 
It remains constant after the saturated solution has occurred.   12 

Solubility remains constant at the temperature where evaporation 
begins.  

10 

Solubility is a distinctive characteristic and therefore remains 
unchanged.  

3 

Total 80 
(100%) 

 80 

 

 
Figure 8 Distribution of the PPSTs’ drawings in response to the fifth question by categories 

 

Incorrect drawing Partially correct drawing 
 

Correct drawing 

Figure 9 Examples of the PPSTs’ drawings in response to the fifth question 
 

f = 5 (6%)
f = 15 (19%)

f = 54 (67.5%)

f = 6 (7.5%)

Correct drawing
Partially correct drawing
Incorrect drawing
N/A



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  187 J.Sci.Learn.2022.5(1).176-192 
  

the result of analysis of the PPSTs' statements to the fifth 
question as to the chemical representation levels, we found 
that these statements were at macroscopic and sub-
microscopic levels (see Table 9). Although the PPSTs had 
mostly incorrect drawings, their statements corresponded 
to the macroscopic and sub-microscopic levels. The 
macroscopic statements include scientifically correct 
responses expressing that saturated solution occurs (f = 19) 
and a more concentrated solution is formed than the 
previous salt-water solution (f = 18). Some PPSTs (f = 17) 
were also observed to refer to a visible phenomenon where 
water blurs as salt dissolves in the water.  This finding 
indicates that the PPSTs had statements matching with the 

macroscopic level. To assess the statements in terms of 
scientific accuracy, despite being sub-microscopic 
responses, these statements show that the PPSTs 
misunderstood that the distance between salt particles 
shrinks to get closer to each other. Among the study results 
is also the inability of most of the prospective teachers to 
draw the saturated solution at the sub-microscopic level. 
The great difficulty is caused by their inability to consider 
how the ions in the solution would move. Many studies 
have shown that prospective teachers find it challenging to 
understand the representation of particles existing in 
solution (Adadan, 2014; Demirbaş et al., 2011; Valanides, 
2000). However, the macroscopic statements of the 

Table 9 The results of the analysis of the PPSTs’ responses to the fifth question 

Representation 
Levels 

Statements Frequency values 
of the statements 

Macroscopic  The saturated solution occurs. 19 

It becomes more concentrated. The amount of salt in the mixture increases.  18 

A blurry appearance occurs as salt dissolves in it. It becomes oversaturated.  17 

Salt gets more intense than water. 8 

Salt does not dissolve. It sinks to the bottom. 5 

The ratio of salt to water increases in the mixture. Dissolution time prolongs.  2 

Total  69 

Sub-
microscopic  

The distance between particles shrinks if the amount of salt in the mixture 
increases.  

7 

Salt particles move closer to each other. 4 

Total  11 

 
Table 10 The results of the analysis of the PPSTs' responses to question 6a 
Representation 

Levels 
Statements Frequency values 

of the statements 

Macroscopic Salt does not filter through the paper filter. Instead, it is separated through 
filtering.  

31 

The total amount of the solution filters through the paper filter. The salt has 
already dissolved in the water. 

10 

Some amount of the salt does not filter through the paper filter. Instead, the 
dissolved part is filtered into the Erlenmeyer flask.   

14 

The solution thoroughly filters through the paper filter, except for the 
substances that have not dissolved in the water.  

22 

Total  77 

Sub-
microscopic 

The separated substances stay on the filter: Sodium and chloride.  3 

Total  3 

 

 
Figure 10 PPSTs' responses to question 6a presented with their frequency and percentage distribution by categories 

 

f = 22  (27%)

f = 10 (13%)f = 48 (60%)

Correct response

Partially correct response

Incorrect response



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  188 J.Sci.Learn.2022.5(1).176-192 
  

prospective teachers concerning the saturated salt-water 
solution coincide with scientific accuracy. So, this shows 
that they do not have problems with the visible dimensions 
of phenomenon or phenomena but with the invisible 
particle behaviors as seen in their statements and drawing. 
So mental modeling and a greater degree of interpretation 
are required to overcome the obstacles of this sub-
microscopic level and understand the information 
conveyed in the representation (Head et al., 2017). 

The next question (6a) that the PPSTs were asked: 
"What would you expect to happen if you pour the hot salt-
water solution into a filter paper?". Figure 10 shows that 
more than half (60%) of them had incorrect answers, while 
those with correct answers accounted only for 27%, and 
partially-correct answers accounted for 13%. As question 
6a has a sensate basis of observation, it is a question 
regarding the macroscopic level. The representation levels 
indicate that most PPSTs had macroscopic statements (see 
Table 10). From the macroscopic statements of the PPSTs, 
we concluded that they had many miscomprehensions. For 
example, they stated that salt separates from water through 
filtering (f = 26), and the quantity of non-dissolved salt 
does not filter through the filter paper (f = 14). This finding 
shows that the PPSTs could not explain filtering, which is 
one of the mixture separation methods.  Despite the 
experiment and video demonstrated to facilitate 
comprehension of a chemistry subject, the prospective 

teachers could not distinguish the mixtures from each 
other. Wang, Chi, Luo, Yanga, & Huanga (2017) stated that 
to understand chemical processes such as filtering and 
crystallization, symbolic representations should be 
included in the learning process of learners and 
macroscopic representations.  

In another question (6b) asked the PPSTs, they were 
instructed to draw how the particles formed in the flask and 
explain the reasons for their drawings. In Table 11, the 
results of the analysis of the PPSTs' drawings revealed that 
62.5% of them had correct drawings, while 32.5% of them 
had incorrect drawings. Those with incorrect drawings 
illustrated the salt particles attached (f = 9), solidified (f = 
10), or freeze (f = 7) (see Figure 11). These findings 
demonstrate that they confuse crystallization with freezing, 
and they could be unable to think that the crystals forming 
in crystallization are separated from the solvent. The 
prospective teachers described the crystallization of salt 
particles as freezing and solidification, demonstrating that 
they confused crystallization with freezing, although they 
are two different phenomena. This situation reveals that 
the prospective teachers completed the science courses of 
primary and secondary schools where basic concepts are 
learned and the chemistry course of the grade-1 high school 
with inadequate and inaccurate knowledge. Nevertheless, 
many studies are emphasizing that science subjects should 
be taught effectively, especially in the learning process 

Table 11 The results of the analysis of the PPSTs’ responses to the question 6b 

Levels f and % 
values 

Statements Frequency values 
of the statements 

Correct 
drawing 

50 (62.5%) It is crystallized. Because salt particles are dissolving in water, move 
closer.  

28 

The particles left on the string are salt crystals.  12 
The only salt remains as the water evaporates.  10 

Incorrect 
drawing 

26 (32.5%) It is a solidified form. 10 
Salt particles are attached to each other.  9 

It is frozen. 7 
N/A 4 (5%)  4 

Total 80 (100%)  80 

 

 
Incorrect drawing 

 
Correct drawing 

Figure 11 Examples of the graphs drawn by the PPSTs in response to question 6b 
 
 

 



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  189 J.Sci.Learn.2022.5(1).176-192 
  

extending from primary education to university, and 
therefore by providing transitions at macro, symbolic and 
sub-microscopic levels (Aydeniz et al., 2017; Derman & 
Ebenezer, 2020; Kelly et al., 2017; Tsaparlis et al., 2010). 

The final seventh question investigated the other 
mixtures that the PPSTs might know can be separated 
through crystallization. Again, 80% of them responded, 
referring to sugar-water solution (see Figure 12).  

When all the findings were considered, it was revealed 
that the PPSTs could not think in a triple structure 
(macroscopic, sub-microscopic, and symbolic) and could 
not combine them in related content of the crystallization 
experiment. As emphasized in the literature (Banawi et al., 
2019; Derman & Ebenezer, 2020; Hermita et al., 2020) and 
found in this study, the understanding of prospective 
primary school teachers require to include macroscopic, 
sub-microscopic, and symbolic levels. 
 
CONCLUSION 

The subject "Science" at the primary education contains 
specific and basic chemistry concepts such as 
homogeneous and heterogeneous mixtures, water and 
water solutions, dissolving, and crystallization (Januik & 
Mazur, 2010). Therefore, prospective teachers who are well 
trained in these subjects are needed in teaching to ensure 
quality science education. Our results herein revealed that 
the prospective teachers had inadequate knowledge about 
the relevant chemistry concepts. Moreover, the responses 
of the prospective teachers discovered the existing 
problems that they have in terms of chemical 
representations. The results also demonstrated that their 
responses were mainly at the macroscopic level, while they 
had great difficulty explaining at the sub-microscopic and 
symbolic representations levels. This result shows that the 
students of the prospective teachers may also have weak 
knowledge in their professional lives. It will lead to the fact 
that there are students who cannot respond to the invisible 
state of matter in daily life. They cannot perform 
meaningful learning because they cannot establish a 

relationship between representations. Therefore, it is 
expected that prospective teachers who can understand the 
microscopic world and teach it by simplifying it will be 
trained (Nandiyanto et al., 2018). Additionally, the results 
of this study intensify the data of prospective primary 
school teachers' understanding of the crystallization 
experiment. Hence they become the inspiration to ensure 
quality science education and further research. 

Many studies show that primary school students at the 
concrete operational stage have difficulty comprehending 
such concepts as chemical change, physical change, 
dissolution, heterogeneous mixture, and homogenous 
mixture unless they associate them with daily-life 
phenomena (Donovan & Bransford, 2005; Taşdemir & 
Demirbaş, 2010). For this reason, PPSTs should teach 
these concepts by using macroscopic statements and 
employing sub-microscopic drawings and representations 
that might appeal to students' concrete learning. 
Papageorgiou, Amariotakis, and Spiliotopoulou (2017) 
pointed out that chemical representations serve as a basis 
for the constructed internal representation and help 
students consolidate their understanding of an abstract 
concept. It is also expressed that employing various 
instructional technologies such as animations for these 
representations helps reinforce concrete learning of these 
concepts (Kelly & Jones, 2008; Pekdağ, 2010). In our study, 
the prospective teachers have displayed an animated video 
along with the demonstration experiment, which also 
served as a model in teaching these concepts.  

The participants of the study have a remarkable impact 
on our results. Many studies in the literature report that 
prospective teachers have negative emotions rather than 
positive emotions when teaching topics related to physics 
or chemistry since the participants are prospective primary 
school teachers (Brígido, Bermejo, Conde, & Mellado, 
2010). When the negative attitudes of prospective teachers 
are reflected upon concepts of physics or chemistry, their 
students might have difficulties in learning. Therefore, 
prospective teachers should get acquainted with physics 

 
 

 
Figure 12 PPSTs' responses to question 7 presented with their frequency and percentage distribution 

 

No response
f = 8 (10%)

Sugar-water 
mixture 

f = 64 (80%)

Lime water  
f = 5 (6%)

Naphthalene
-water 

mixture 
f = 2 (3%)

Snowflakes 
f = 1 (1%)



Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  190 J.Sci.Learn.2022.5(1).176-192 
  

and chemistry concepts and learn the conceptual structures 
properly to develop a positive attitude towards teaching 
these concepts. Implementing science activities in primary 
education also poses an issue concerning science concepts. 
For this reason, more effective science training programs 
should be arranged to use science activities frequently and 
effectively (Papageorgiou, Kogianni, & Makris, 2007).  

The present study allowed prospective teachers to 
explain chemical phenomena using their conceptual 
structures at different chemical representation levels, 
thereby allowing them to get curious about and interested 
in exploring chemistry. There have been some 
recommendations developed based on the results and the 
relevant literature: 

• Hands-on science laboratory practices that 
incorporate different teaching techniques supporting 
primary school teachers and teaching basic chemistry 
concepts can be implemented in demonstration and as 
teamwork. Prospective teachers might therefore be allowed 
to get more experience on science concepts.  

• Difficulties experienced at any level of chemical 
representation might affect comprehension of other 
representation levels; thus, determining their state of 
comprehension at all three levels is critically important to 
ensure efficient teaching of basic science concepts in 
chemistry. Therefore, teaching plans should be designed in 
a way attaching importance to these representation levels 
in teaching basic science concepts such as dissolution, 
solubility, and crystallization.  

• PPSTs must attend a quality science teaching so 
primary school students, who will encounter the subjects 
and basic concepts of science for the first time, acquire 
accurate knowledge of the basic science subjects and 
concepts. To raise the quality of science teaching, the 
education curricula of prospective primary teachers must 
be revised and improved as needed. 

 
REFERENCES   
Aubrey, C., Ghent, K., & Kanira, E. (2012). Enhancing thinking skills in 

early childhood. International Journal of Early Years Education, 20(4), 
332-348. 

Adadan, E. (2014). Investigating the influence of pre-service chemistry 
teachers' understanding of the particle nature of matter on their 
conceptual understandings of solution chemistry. Chemistry 
Education Research and Practice, 15(2), 219-238. 
https://dx.doi.org/10.1039/C4RP00002A 

Akkuzu Güven, N., & Uyulgan, M. A. (2021). Linking the representation 
levels to a physical separation and purification method in 
chemistry: Understanding of distillation experiment. Journal of 
Pedagogical Research, 5 (3), 80-104. 
https://doi.org/10.33902/JPR.2021370703 

Aydeniz, M., Bilican, K., & Kirbulut, Z. D. (2017). Exploring pre-service 
elementary science teachers’ conceptual understanding of 
particulate nature of matter through three-tier diagnostic test. 
International Journal of Education in Mathematics, Science and Technology, 
5(3), 221-221.  

Banawi, A., Sopandi, W., Kadarohman, A., & Solehuddin, M. (2019). 
Prospective primary school teachers’ conception change on states 
of matter and their changes through predict-observe-explain 

strategy. International Journal of Instruction, 12(3), 359-374. 
https://doi.org/10.29333/iji.2019.12322a 

Barak, M., & Dori, Y. J. (2004). Enhancing undergraduate students’ 
chemistry understanding through project-based learning in an it 
environment. Science Education, 8(1), 117-139. 

Brígido, M., Bermejo, M. L., Conde, C., & Mellado, V. (2010).  The 
emotions in teaching and learning nature sciences and 
physics/chemistry in pre-service primary teachers. US-China 
Education Review, 7(12), 25-32. 

Buss, R. R. (2010). Efficacy for teaching primary science and 
mathematics compared to other content. School Science and 
Mathematics, 110(6), 290-297. http://dx.doi.org/10.1111/j.1949-
8594.2010.00037.x  

Canpolat, N., & Pınarbaşı, T. (2012). Kimya öğretmen adaylarının 
kaynama olayı ile ilgili anlayışları: Bir olgubilim çalışması 
[Prospective chemistry teachers’ understanding of boiling: a 
phenomenological study]. Erzincan University Journal of Education 
Faculty, 14(1), 81-96. 

Coştu, B., Ayas, A., Açıkkar, E., & Çalık, M. (2007). Çözünürlük 
konusuyla ilgili kavramlar ne düzeyde anlaşılıyor? [At which level 
are concepts about solubility topic understood?]. Boğaziçi University 
Journal of Education, 24(2), 13-28. 

Coştu, B., Ayas, A., Çalık, M., Ünal, S., & Karataş, F. Ö. (2015). Fen 
öğretmen adaylarının çözelti hazırlama ve laboratuvar 
malzemelerini kullanma yeterliliklerinin belirlenmesi [Determining 
preservice science teachers’ competences in preparing solutions 
and in use of laboratory tools]. Hacettepe University Journal of 
Education, 28(28), 65-72.  

Council of Higher Education [CoHE]. (2018). Sınıf öğretmenliği lisans 
programı, yeni öğretmen yetiştirme lisans programları [Primary education 
undergraduate program, new teacher training undergraduate 
programs]. 

Creswell, J. W. (2012). Educational research: Planning, conducting, and 
evaluating quantitative and qualitative research. Educational Research 
Vol. 4 (pp. 232-260). Harlow, United Kingdom: Pearson Education 
Limited. 

Demirbaş, M., Tanrıverdi, G., Altınışık D., & Şahintürk, Y. (2011). Fen 
bilgisi öğretmen adaylarının çözeltiler konusundaki kavram 
yanılgılarının giderilmesinde kavramsal değişim metinlerinin etkisi 
[The impact of conceptual change texts on the elimination of 
misconceptions of science teacher candidates about the subject of 
solution]. Sakarya University Journal of Education, 1(2), 52-69. 

Demircioğlu, H., Demircioğlu, G., & Ayas, A. (2004). Sınıf öğretmeni 
adaylarının bazı temel kimya kavramlarını anlama düzeyleri ve 
karşılaşılan yanılgılar [Prospective science teachers' levels of 
understanding and misconceptions about some basic chemical 
concepts]. HAYEF: Journal of Education, 1, 29-49. 

Derman, A., & Ebenezer, J. (2020).  The effect of multiple 
representations of physical and chemical changes on the 
development of primary pre-service teachers cognitive structures. 
Research in Science Education, 50, 1575–1601. 
https://doi.org/10.1007/s11165-018-9744-5  

Donovan, M. S., & Bransford, J. D. (Eds.). (2005). How students learn: 
History, mathematics, and science in the classroom. Washington, DC: 
National Academies Press. 

Duschl, R. A., Schweingruber, H. A., & Shouse, A. W. (Eds.). (2007). 
Taking science to school: Learning and teaching science in grades K-8. 
Washington, DC:  National Academies Press. 

Eilks, I., & Hofstein, A. (Eds.). (2015). Relevant chemistry education: From 
theory to practice. Rotterdam: Sense Publishers. 

Gheith, E. M., & Aljaberi, N. M. (2015). Pre-service classroom teachers’ 
attitudes toward graphs and their ability to read and interpret them. 
International Journal of Humanities and Social Science, 5(7), 113-124. 

Glazer, N. (2011). Challenges with graph interpretation: a review of the 
literature. Studies in Science Education, 47(2), 183-210. 

Håland, B. (2010). Student-teacher conceptions of matter and 
substances – evaporation and dew formation. Nordina, 6(2), 109–
124.  

https://dx.doi.org/10.1039/C4RP00002A
https://doi.org/10.29333/iji.2019.12322a
http://dx.doi.org/10.1111/j.1949-8594.2010.00037.x
http://dx.doi.org/10.1111/j.1949-8594.2010.00037.x
https://doi.org/10.1007/s11165-018-9744-5


Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  191 J.Sci.Learn.2022.5(1).176-192 
  

Härmälä-Braskén, A.-S., Hemmi, K., & Kurtén, B. (2020). 
Misconceptions in chemistry among Finnish prospective primary 
school teachers-a long-term study. International Journal of Science 
Education, 42(9), 1447-1464.   

Head, M. L., Yoder, K., Genton, E., & Sumperl, J. (2017). A quantitative 
method to determine pre-service chemistry teachers' perceptions 
of chemical representations. Chemistry Education Research and Practice, 
18(4), 825-840. 

Herga, N. R., Čagran, B., & Dinevski, D. (2016). Virtual laboratory in 
the role of dynamic visualisation for better understanding of 
chemistry in primary school. Eurasia Journal of Mathematics, Science & 
Technology Education, 12(3), 593-608. 

Hermita, N., Alpusari, M., Noviana, E., Putra, Z. H., Islami, N., Basori, 
H., Suhandi, A., & Samsudin, A. (2020). Improving prospective 
primary school teachers' mental models through implementation 
of CDOI supported by multimode visualization. Universal Journal of 
Educational Research, 8(2), 460-467. 
https://doi.org/10.13189/ujer.2020.080217  

Januik, R. M., & Mazur, P. (2010). Poland. In B. Risch (Ed.), Teaching 
chemistry around the world (pp. 291-309). Germany: Hubert &Co. 

Johnstone, A. H. (2000). Teaching of chemistry-logical or psychological? 
Chemistry Education Research and Practice, 1(1), 9–15. 

Johnstone, A. H. (2010). You can’t get there from here. Journal of Chemical 
Education, 87(1), 22–29. https://dx.doi.org/10.1021/ed800026d 

Juriševič, M., Glažar, S. A., Razdevšek Pučko, C., & Devetak, I. (2008). 
Intrinsic motivation of pre-service primary school teachers for 
learning chemistry in relation to their academic achievement. 
International Journal of Science Education, 30(1), 87–107. 
https://dx.doi.org/10.1080/09500690601148517 

Kabapinar, F., Leach, J., & Scott, P. (2004). The design and evaluation 
of a teaching-learning sequence addressing the solubility concept 
with Turkish secondary school students. International Journal of 
Science Education, 26(5), 635—65. 

Kelly, R. M., & Jones, L. L. (2008). Investigating students' ability to 
transfer ideas learned from molecular animations of the dissolution 
process. Journal of Chemical Education, 85(2), 303.  

Kelly, R. M., Akaygün, S., Hansen, S. J. R., & Villalta-Cerdas, A. (2017). 
The effect that comparing molecular animations of varying 
accuracy has on students' submicroscopic explanations. Chemistry 
Education Research and Practice, 18(4), 582–600. 

Knowles, M., Holton, E. F., & Swanson, R. A. (2005). The adult learner: 
the definitive classic in adult education and human resource development (6th 
ed.). Amsterdam: Elsevier. 

Kozma, R. (2003). The material features of multiple representations and 
their cognitive and social affordances for science understanding. 
Learning and instruction, 13(2), 205-226. 

Kurt, S., & Birinci Konur, K. (2017). Pre-service primary teachers’ 
impressions towards chemistry experiments based on 
constructivist laboratory approach. Inonu University Journal of the 
Faculty of Education, 18(3), 145-161. 
http://dx.doi.org/10.17679/inuefd.296545  

Lemma, A. (2013). A diagnostic assessment of eight grade students’ and 
their teachers’ misconceptions about basic chemical concepts. 
African Journal of Chemical Education, 3(1), 39–59. 

Lindawati, L., Wardani, S., & Sumarti, S. S. (2019). Development of 
inquiry materials based on chemical representation to improve 
students’ critical thinking ability. Journal of Innovative Science Education, 
8(3), 332-343. https://doi.org/10.15294/JISE.V8I1.31082 

Mansfield, C. F., & Woods-McConney, A. (2012). “I didn’t always 
perceive myself as a science person”: Examining efficacy for 
primary science teaching. Australian Journal of Teacher Education, 
37(10),37-52. 

Merino, C., & Sanmarti, N. (2008). How young children model chemical 
change. Chemistry Education Research and Practice, 9(3), 196–207. 

Merriam, S. B. (1988). Case study research in education:  a qualitative approach. 
San Francisco: Jossey-Bass. 

Miles, M. B., & Huberman, A. M. (1994). Qualitative data analysis. United 
States of America Printed. 

Nandiyanto, A. B. D., Asyahidda, F. N., Danuwijaya, A. A., Abdullah, 
A. G., Amelia, N., Hudha, M. N., & Aziz, M. (2018). Teaching 
“nanotechnology” for elementary students with deaf and hard of 
hearing. Journal of Engineering Science and Technology, 13(5), 1352-1363. 

Okumuş, S., Öztürk, B., Doymuş, K., & Alyar, M. (2014). Maddenin 
tanecikli yapısının mikro ve makro boyutta anlaşılmasının 
sağlanması [Aiding comprehension of the particulate of matter at 
the micro and macro levels]. Journal of Educational Sciences Research, 
4(1), 349-368. 

Papageorgiou, G., Amariotakis, V., & Spiliotopoulou, V. (2017). Visual 
representations of microcosm in textbooks of chemistry: 
constructing a systemic network for their main conceptual 
framework. Chemistry Education Research and Practice, 18(4), 559-571. 
http://dx.doi.org/10.1039/C6RP00253F. 

Papageorgiou, G., Kogianni, E., & Makris, N. (2007). Primary teachers’ 
views and descriptions regarding some science activities. Chemistry 
Education Research and Practice, 8(1), 52–60. 
https://dx.doi.org/10.1039/B6RP90019D 

Pekdağ, B. (2010). Kimya öğreniminde alternatif yollar: animasyon, 
simülasyon, video ve multimedya ile öğrenme [Alternative methods 
in learning chemistry: learning with animation, simulation, video 
and multimedia]. Journal of Turkish Science Education Volume 7(2), 79-
110. 

Pine, K., Messer, D., & St. John, K. (2001). Children’s misconceptions 
in primary science: A survey of teachers’ views. Research in Science 
and Technological Education, 19(1), 79–96. https://dx.doi.org/ 
10.1080/02635140120046240. 

Petersen, J. E., & Treagust, D. F. (2014). School and university 
partnerships: The role of teacher education institutions and 
primary schools in the development of pre-service teachers' science 
teaching efficacy. Australian Journal of Teacher Education, 39(9), 153-
167. http://dx.doi.org/10.14221/ajte.2014v39n9.2. 

Polifka, J. (2021). Investigating introductory science students’ knowledge of multiple 
representations using technology. (Doctoral Dissertation). Retrieved 
from 
https://www.proquest.com/pqdtglobal/docview/2572566476/pr
eviewPDF/DB243A053C284C6BPQ/1?accountid=10527. 

Sanchez, J. M. P. (2021). Understanding of kinetic molecular theory of 
gases in three modes of representation among tenth-grade students 
in chemistry. International Journal of Learning, Teaching and Educational 
Research, 20(1), 48-63. https://doi.org/10.26803/ijlter.20.1.3 

Schulte, P. L. (2001). Pre-service elementary teachers' alternative conceptions in 
science and attitudes toward teaching science. (Doctoral Dissertation). 
Retrieved from https://www.proquest.com/docview/304703069  

Sopandi, W., Kadarohman, A., Rosbiono, M., Latip, A., & Sukardi, R. R. 
(2018). The courseware of discontinuous nature of matter in 
teaching the states of matter and their changes. International Journal 
of Instruction, 11(1), 61–76. 
https://dx.doi.org/10.12973/iji.2018.1115a 

Taber, K. S. (2009). Learning at the symbolic level. In J. K. Gilbert & D. 
Treagust (Eds.), Multiple representations in chemical education (pp. 75–
105). Springer, Dordrecht. 

Tarkın Çelikkıran, A., & Gökçe, C. (2019). Kimya öğretmen adaylarının 
çözünürlük konusuna ilişkin submikroskobik seviyedeki anlama 
düzeylerinin çizimlerle belirlenmesi [Determination of preservice 
chemistry teachers’ understanding of solubility concept at 
submicroscopic level by drawings]. Pamukkale University Journal of 
Education, 46, 57-87. http://dx.doi.org/10.9779/pauefd.457845 

Taşdemir, A., & Demirbaş, M. (2010). İlköğretim öğrencilerinin fen ve 
teknoloji dersinde gördükleri konulardaki kavramları günlük 
yaşamla ilişkilendirebilme düzeyleri [The level of correlation of 
concepts that primary students seen topics in science and 
technology class with daily life]. International Journal of Human 
Sciences, 7(1), 124-148. 

Taylor, N., & Coll, R. K. (2002). Pre-service primary teachers' models of 
kinetic theory: an examination of three different cultural groups. 
Chemistry Education Research and Practice, 3(3), 293-315. 

https://doi.org/10.13189/ujer.2020.080217
http://dx.doi.org/10.17679/inuefd.296545
https://doi.org/10.26803/ijlter.20.1.3
https://www.proquest.com/docview/304703069


Journal of Science Learning   Article 
 

DOI: 10.17509/jsl.v5i1.34772  192 J.Sci.Learn.2022.5(1).176-192 
  

Tepe, O., & Akkuzu Güven, N. (2020). Genel kimya konularına ilişkin 
grafik okuma, yorumlama ve çizim becerileri testi geliştirme süreci: 
Geçerlilik ve güvenilirlik analizleri [The development process of 
graph reading, interpreting and drawing skills test concerning 
general chemistry subjects: validity and reliability analyses]. Western 
Anatolia Journal of Educational Sciences, 11(1), 23-43. 

Treagust, D. F., Chandrasegaran, A. L., Crowley, J., Yung, B. H. W., 
Cheong, I. P. A, & Othman, J. (2010). Evaluating students’ 
understanding of kinetic particle theory concepts relating to the 
states of matter, changes of state and diffusion: a cross-national 
study. International Journal of Science and Mathematics Education, 8, 141-
164. 

Tsaparlis, G., Kolioulis, D., & Pappa, E. (2010). Lower-secondary 
introductory chemistry course: A novel approach based on science-
education theories, with emphasis on the macroscopic approach, 
and the delayed meaningful teaching of the concepts of molecule 
and atom. Chemistry Education Research and Practice, 11(2), 107–117. 

Uluçınar Sağır, Ş., Tekin, S., & Karamustafaoğlu, S. (2012). Sınıf 
öğretmeni adaylarının bazı kimya kavramlarını anlama düzeyleri 
[The levels of prospective elementary school teachers’ 
understanding of some chemistry concepts]. Journal of Dicle 
University Ziya Gökalp Faculty of Education, 19, 112-135. 

Uludüz, Ş. M. (2017). Sınıf öğretmeni adaylarının fen okuryazarlık düzeyleri ile 
fen öğretimi öz yeterlik inançlarının karşılaştırılması [The comparison of 
science literacy levels of primary teacher candidates and science 
teaching self efficacy beliefs]. (Master thesis). Retrieved from 
https://tez.yok.gov.tr/UlusalTezMerkezi/  

Valanides, N. (2000). Primary student teachers' understanding of the 
particulate nature of matter and its transformations during 
dissolving. Chemistry Education: Research and Practice in Europe, 1(2), 
249- 262. 

Wach, E., & Ward, R. (2013). Learning about qualitative document analysis. 
Retrieved from 
https://opendocs.ids.ac.uk/opendocs/handle/20.500.12413/298
9    

Wang, Z., Chi, S., Luo, M., Yanga, Y., & Huanga, M. (2017). 
Development of an instrument to evaluate high school students’ 
chemical symbol representation abilities. Chemical Education Research 
and Practice, 18(4), 875-892. 
https://doi.org/10.1039/C7RP00079K 

Wu, H. K., & Puntambekar, S. (2012). Pedagogical affordances of 
multiple external representations in scientific processes. Journal of 
Science Education and Technology, 21(6), 754-767. 

Ye, J., Lu, S., & Bi, H. (2019). The effects of microcomputer-based 
laboratories on students macro, micro, and symbolic 
representations when learning about net ionic reactions. Chemistry 
Education Research and Practice, 20(1), 288-301. 
http://dx.doi.org/10.1039/c8rp00165k 

Yerrick, R. K., & Simons, T. (2017). The affordances of fiction for 
teaching chemistry. Science Education International, 28(3), 232-243. 

Yıldırım, A., & Şimşek, H. (2013). Sosyal bilimlerde nitel araştırma yöntemleri 
[Qualitative research methods in the social sciences]. Ankara: 
Seçkin Kitabevi. 

 

NOTES 
A part of this study is presented as an oral presentation 

at the 2nd International Congress on Seeking New 
Perspectives in Education. 

 
ABBREVIATIONS 

PPSTs, Prospective Primary School Teachers; N/A, 
No answer.

https://opendocs.ids.ac.uk/opendocs/handle/20.500.12413/2989
https://opendocs.ids.ac.uk/opendocs/handle/20.500.12413/2989
http://dx.doi.org/10.1039/c8rp00165k