a 
  

© 2020 Indonesian Society for Science Educator 41 J.Sci.Learn.2020.4(1).41-49 

 

Received:  14 May 2020 

Revised: 23 November 2020 

Published: 28 November 2020 

 

 

Effect on Academic Achievement and Misconceptions of Pre-service 
Teachers through Combining Different Teaching Methods in a Preschool 
Science Course  

Nur Akcanca1*, Lale Cerrah Özsevgeç2 

1Early Childhood Education, Çanakkale Onsekiz Mart Üniversitesi, Turkey 
2Primary Education, Karadeniz Teknik Üniversitesi, Turkey 
 
*Corresponding author: nurakcanca@comu.edu.tr  
 

ABSTRACT This study aimed to investigate the effects of different active teaching techniques on pre-school student teachers' 
concept learning and academic achievement. The study group consisted of 46 third year pre-school student teachers in a public 
university. Different active teaching methods were used during the single term Science Course, a compulsory course in the Preschool 
Programme. The treatment process took ten weeks in total (4 hours per week). The study had both qualitative and quantitative data. 
The quantitative data were collected using a three-tiered science concepts test, and qualitative data were collected through observation 
by the researcher. The alpha Cronbach values calculated for the test's reliability were 0.642 for Success-1 (S1) and 0.52 for 
Misconception-3 (MC3) scores. A dependent t-test was used to compare the pre and post-test scores of the pre-school student 
teachers. The researcher took observation notes during the in-class teaching exercises. The findings revealed that there were 
significant differences between the student teachers' pre and post-test scores. They understood science concepts significantly better 
by the end of the course. It is concluded that combining different teaching methods enhances science concept understanding among 
student teachers.  In addition, misconceptions decreased after instruction. 

Keywords Active teaching methods, Success, Conceptual understanding, Science education, Pre-school student teachers 

1. INTRODUCTION 
Preschool constitutes the first stage of the education 

system and uses a different education process from the 
other education stages. Preschool education program is 
planned by considering the characteristics of children's 
physical, mental, and emotional development. Pre-school 
education aims to prepare children for elementary 
education by developing their language, motor, and 
cognitive skills (Ministry of National Education [MoNE], 
2013). At this stage, children are expected to develop their 
fine motor skills, express themselves well, and acquire self-
care skills. Furthermore, they are expected to recognize, 
categorize, and order the scientific phenomena occurring 
around them at a basic level. In this context, Turkish, 
science, mathematics, and art activities are used in 
education not as an aim but as a means for children's 
development in various aspects. 

In the pre-school period, science is a part of children's 
games, investigations, inquiries, and experiences (Tahta & 
İvrendi, 2010). Children at these ages are directly involved 
in relationships with living creatures and each other. Many 

scientific concepts include the sky, sun, moon, heat, 
temperature, sound, weight, environment, and 
environmental problems. Accordingly, many scientific 
concepts are constructed in minds during this life period 
(Demir & Şahin, 2015).  Meaningful construction of 
scientific concepts in the early stages is essential to facilitate 
future learning. While teaching new concepts, the teacher 
uses the students' previous knowledge. There are science 
activities in the Preschool Curriculum to teach some 
science concepts to children.  It is crucial to teach these 
concepts correctly to ease the students' learning and 
teachers' teaching during elementary education (Gemici, 
2008). In this context, it is essential that pre-school 
teachers, who will later be responsible for teaching these 
concepts, have also learned the science concepts correctly. 

The related literature revealed that pre-school student 
teachers lacked competence in teaching scientific concepts 
(Brenneman, 2011). They had problems in knowledge 

mailto:nurakcanca@comu.edu.tr


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DOI: 10.17509/jsl.v4i1.24672 42 J.Sci.Learn.2020.4(1).41-49 
 

levels regarding science concepts (Cho, Kim, & Choi, 2003; 
Kallery, 2004). Çamlıbel Çakmak (2012) revealed that pre-
service pre-school teachers had misconceptions about the 
concepts related to heat and temperature, space, floating 
and sinking, and living things. Moreover, Timur (2012) 
determined that pre-school student teachers possessed 
many misconceptions about force and motion. Ültay & 
Can (2015) concluded that pre-service pre-school teachers 
had knowledge problems related to heat and temperature. 
It is known that when pre-service teachers whom 
themselves possess this incorrect or inadequate 
information, or indeed these misconceptions, are 
appointed to their profession, there is a strong possibility 
that they will transfer these to their students (Çamlıbel 
Çakmak, 2012). Based on the necessity to solve the 
problem at its source, it is crucial that candidates' 
conceptual understanding and knowledge levels are 
improved at the undergraduate level (Özbek, 2009).   

In the pre-school teaching curriculum, there is a course 
named "Teaching Science in Early Childhood". This course 
expects candidates to learn science concepts and acquire 
skills to teach and plan science activities according to their 
children's ages and developmental levels (Alisinanoğlu, 
Özbey, & Kahveci, 2011; Tahta & İvrendi, 2010). 
Furthermore, pre-school teachers are required to 
comprehend the aim of science education in this course. 
They wanted to be equipped with teaching methods to 
make their children active and excited and make their 
learning meaningful (Demir & Şahin, 2014).   In studies 
conducted with pre-school teachers, it was determined that 
teachers experienced difficulties related to planning and 
implementing science activities and to use different 
techniques for teaching scientific concepts (Bilaloğlu, 
Aslan, & Arnas, 2008). The methods such as an educational 
game, semantic network, drama, projects, brainstorming, 
problem-solving should be used to teach science (Sığırtmaç 
& Özbek, 2011).  It is stated that teachers who cannot 
acquire skills at the desired level may be the root of their 
undergraduate education (Orçan, 2013). The study (Ayvacı, 
Devecioğlu, & Yiğit, 2002) revealed that most pre-school 
teachers have limited knowledge about student-based 
teaching methods, and they prefer using traditional 
methods such as lecturing, questioning, and answering, 
demonstration and observation. It has been revealed that 
the science courses at the undergraduate level need revision 
in terms of their content as well as the methods and 
techniques used for the activities and experiments (Kallery, 
2004; Bilaloğlu et al., 2008; Çamlıbel Çakmak, 2012). It is 
considered that a lesson procedure in which the active 
participation of pre-service teachers is enabled and science 
concepts are taught with applications can be helpful about 
increasing the quality of learning and reducing problems 
that may occur in the future (Okur Akçay, 2014; Demir & 
Şahin, 2015). It is also believed that science instruction 

delivered within such a framework will eliminate existing 
misconceptions (Ültay & Can, 2015).   

In line with all this information, it was decided to 
combine some techniques which were stated as useful for 
science teaching education in the literature. So the main 
problem of this research consists of the question, "To what 
extent will a science instruction process, conducted by 
combining different active teaching methods that place the 
student at the center, be effective for pre-school student 
teachers' learning of science concepts?" Using more than 
one teaching technique serves different learning 
preferences of the other learners in the class. Thus it 
strengthens understanding more effectively. It is thought 
that the findings obtained in this study will make positive 
contributions to the planning of science courses at the 
undergraduate level and serve as a guide to faculty 
members teaching these courses. 

This study aims to determine pre-school student 
teachers' learning and evaluate the effect of science 
education courses conducted with different teaching 
methods on success and conceptual understandings of pre-
school student teachers (PSTs). 

 

2. METHOD  

2.1 Research Model 
In this study, one type of pre-experimental design, 

single-group pretest-posttest design, was used.  During the 
study, one group is exposed to a treatment or condition, 
and then the results of the process are measured. A 
different control group was not used to evaluate this 
external intervention's effectiveness better, and a single 
group was worked. Since the aim was to examine in detail 
the student teachers' conceptual changes and achievement 
levels before and following the intervention, a single-group 
pre, and post-test practical research design model was used 
(Frankel & Wallen, 2003). 

2.2 Research Group 
The sample of the study was in a state university located 

in Kars, Turkey. For the selection of the participants, a 
purposive sampling approach was used. Use of this 
sampling technique is preferred in exceptional cases that 
have specific criteria and characteristics (Büyüköztürk, 
Kılıç Çakmak, Akgün, Karadeniz, & Demirel, 2014). In this 
study, 46 (35 females, 11 males) third-year pre-service 
students were selected for the study because they took a 
course titled "Science Education" and were learning 
science topics in this course. At the beginning of the study, 
a pre-test was taken from all student teachers, and then an 
experimental procedure was applied, which was prepared 
by the researchers. The same test was used as a post-test 
after the experimental procedure.    

2.3 Data Collection Tool 
To determine the student teachers' conceptual 

understanding levels and misconceptions related to the 
science concepts specified, a "Three-Tiered Science 



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DOI: 10.17509/jsl.v4i1.24672 43 J.Sci.Learn.2020.4(1).41-49 
 

Concepts Test" (TTSCT) was developed. At the first tier 
of the test, there was a question searching student teachers' 
knowledge. In the second tier, the reasons for the answer 
given to the first question. In addition to the four reasons, 
an 'e' option was given to elicit the PSTs' misconceptions, 
and an adequate space was given for the question "What 
do you think the reason should be?". The third tier was the 
confidence tier to examine whether the PSTs were sure or 
not their previous answers. 

Basic science concepts included in the Science 
Education course comprise three main science fields: life 

sciences, physical sciences, and earth and space sciences 
(Gonzalez et al., 2011; Martin, 2012). The questions 
included in the TTSCT were prepared for the subjects of 
(I) sound, mass, weight, and gravity for physical sciences, 
(ii) living organisms and their categories, global warming, 
and the greenhouse effect for life sciences, and (iii) solar 
system, movements of the Earth, sun, and moon for Earth 
and space sciences. While preparing the TTSCT, firstly, the 
concepts for the relevant science subjects were determined, 
and the misconceptions related to these concepts 
mentioned in the literature were examined. Some of the 

Table 1 Educational activities conducted with PSTs 

Themes/Subjects Activities 

P
h

y
si

c
al

 
S
c
ie

n
c
e
s 

Theme: Matter 
Gravitational force 
Mass and Weight 

Popping balloons (Educational game) 
Who spokes the truth? (Concept cartoon) 
Wet towel and popped balloon (Experiment) 
An apple fell from the sky (Story writing) 
What does a dynamometer look like? (Synthetic) 

E
ar

th
 a

n
d
 

S
p

ac
e
 

S
c
ie

n
c
e
s 

Theme: Space 
Solar System 
Planets 

The Magic School Bus in Space (Cartoon film)  
Look at the first letters (Acrostic activity) 
Examining materials in the solar system 
Spin around me (Creative drama) 
Space journey (Product design) 
What are they talking about-1? (Cartoon completion) 

E
ar

th
 

an
d
 

S
p

ac
e
 

S
c
ie

n
c
e
s Theme: Space 

Movement of the Earth and 
moon 
High/Low Tides 

Giant-dwarf following activity (Educational game) 
What happened to the sun? (Thought-provoking questions) 
Solar and lunar eclipses (Experiment) 
Tidal festival in China (Creative drama) 

L
if

e
 

S
c
ie

n
c
e
s 

Theme: Environment 
-Living Organisms 
-Categories of Living Organisms 

Freeze! (Still image) 
Categorization of living organisms (Presentation) 
Let me categorize living organisms (Semantic network) 
What if it were like this? (Scamper) 
Let’s combine ideas (Bread and butter technique) 

L
if

e
 

S
c
ie

n
c
e
s 

Theme: Environment 
Greenhouse Effect 
Global Warming 

Asya’s letter (Case Study-Creative problem solving) 
Let’s form a committee (Six action shoes) 
Let’s read memos (Conceptual change text) 
Let’s find keywords (Puzzle) 
Migrating birds (Story completion) 

P
h

y
si

c
al

 
S
c
ie

n
c
e
s 

Theme:  
Matter 
Sound 

Who am I? (Puzzles) 
Ali’s voice (Case Study-Creative problem solving) 
What kind of tool is a telephone? (Ordering qualities) 
What are they talking about-2? (Cartoon completion) 
Can you hear me? (Roleplay) 

P
h

y
si

c
al

, 
L

if
e
, 
an

d
 E

ar
th

 a
n

d
 

S
p

ac
e
 S

c
ie

n
c
e
s 

Theme:  
Matter 
Environment  
Space 

Let’s learn while traveling (Station technique) 
What are they talking about-3? (Cartoon completion) 
Let’s write a story (Familiar story adaptation) 
Let’s sing (Song composition) 
Global warming! (Poster preparation) 
Environment friendly (Product development) 
Pitchfork, glass flute, and making a duck sound with vibrations 
(Experiment)  
Lifesaving lunar eclipse (Story completion) 
Design your own space (Product design) 
Grandpa doesn’t sleep (Experiment) 

P
h

y
si

c
al

, 
L

if
e
, 
an

d
 

E
ar

th
 

an
d
 

S
p

ac
e
 

S
c
ie

n
c
e
s 

Theme: Matter-Environment- 
Space 

Let’s make our own mental map (Mental map) 

 



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questions were obtained directly from the sources 
examined, while the lecturers prepared others. 

Furthermore, the changes in the conceptual 
understanding levels of PSTs were determined based on 
the researcher's observation records during the in-class 
teaching practices. The observation data, which included 
video recordings, were systematically evaluated, arranged, 
and reported at each lesson's end. 

2.4 Teaching process 
The research's implementation stage was completed in 

40 hours (4 hours per week). Lessons in which pre and 
post-test were implemented were excluded from this 
period. During the treatment process, which lasted for one 
term, several different techniques were used. Before the 
instruction, other active teaching techniques were planned 
based on the characteristics of the topics. These techniques 
are concept map, semantic network, brainstorming, case 
study, mental map, scamper, role play, creative drama, still 
image, story writing, synthetic, cartoon completion,  six 
action shoes, station technique, creative problem solving, 
thought-provoking questions. 

Some activities were planned as individual projects, 
whereas others were designed for team works to provide 
peer interactions. Members of the groups were determined 
according to classmates with whom they had less 
interaction. The first two weeks of instruction were carried 
out in pre-briefing and introduction to the teaching 
techniques. The activities used for subjects of the science 
education course were given in Table 1. 

2.5 Data Analysis 
For scoring the TTSCT, the responses that PSTs gave 

to each of the three tiers for each question were coded on 
an Excel sheet. The coding was made according to the 
scoring system created by Göksu (2011), and an example 
has been provided to explain how questions were scored. 

PSTs questions in the first three tiers were recorded in 
three categories: correct, incorrect, or misconceptions. If a 
PST chose answer c for item 7, c for 7.1, and a for 7.2. All 
these three answers are correct, and the PST's point was 
recorded as 1 in the correct row, and a score of 0 was 
recorded in both the incorrect and misconceptions rows. 
Coding questions calculate the Success-1 (S1) score as 1 
point if students' teachers' answers to first-tier questions 
are correct. The Success-2 (S2) score is obtained by 
evaluating the students' responses to the items' first and 
second tiers. When a student-teacher selects the correct 
statement at the first tier and chooses the valid reason, 
his/her S2 score was coded as 1, while incorrect and 
misconception lines were coded as 0. Finally, the Success-
3 (S3) score was calculated by taking all three stages into 
account, and coding was made as 1 point in case of 
certainty for the answer. 

They were assuming that PST chose answer d for 
question 7, d for 7.1, and 7.2. Since a response of d 
indicates that the respondent has misconceptions regarding 
this question's content, a score of 1 was recorded in the 
misconceptions row. A response of d in Tier 2 supports the 
same misconception. A score of 1 was recorded in the 
misconceptions row. The respondent indicated that he was 
confident of the response he gave in Tier 1 by selecting a 
response in Tier 3. All these scores were taken into 
consideration when calculating the PST's Misconception-1 
(MC1), Misconception-2 (MC2), and Misconception-3 
(MC3) points. An independent t-test was performed for the 
scores obtained by the PSTs' pre, and post-test. 

Observational data consisted of both in-class 
observational notes, and video recordings were analyzed 
together with personal documents. The data obtained from 
these documents were used to support or refute the data 
collected during observations or offer an alternative 
interpretation of the study's findings. 

Table 2 Dependent t-test analysis of PSTs’ pre and post-test Success-1, 2, and 3 scores on the TTSCT 

Class Test N �̅� S SD t p 

TTSCT S1 Pre-test 46 6.98 3.84 45 5.96 .000* 

Post-test 46 10.20 2.17 

TTSCT S2 Pre-test 46 6.87 3.84 45 6.08 .000* 

Post-test 46 10.17 2.24 
TTSCT S3 Pre-test 46 5,17 3,47 45 8.05 .000* 

Post-test 46 8,89 2,47 

*p<.05 
Table 3 Dependent t-test analysis of PSTs’ pre and post-test Misconception-1, 2, and 3 scores on the TTSCT 

Class Test N �̅� S SD t p 

TTSCT MC1 Pre-test 46 6.98 3.75 45 5.99 .000* 

Post-test 46 3.78 1.87 

TTSCT MC2 Pre-test 46 6.89 3.79 45 5.81 .000* 

Post-test 46 3.74 1.93 

TTSCT MC3 Pre-test 46 5.61 4.18 45 4.94 .000* 

Post-test 46 2.72 1.98 

*p<.05 
 



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2.6. Validity and Reliability of Data Collection Tools 
Content validity of the TTSCT was examined by 

calculating incorrect negative and incorrect positive 
numbers. A false negative case is selecting the wrong 
answer for the first tier of the question and choosing the 
second tier's right reason. An incorrect positive case is 
selecting correct answers and a false explanation of the 
reason (Hestenes & Halloun, 1995). Furthermore, 
choosing the correct answer and the correct explanation of 
the reason is defined as scientific knowledge; however, 
giving an incorrect answer and a false explanation is 
defined as knowledge deficiency (Peşman, 2005; Göksu, 
2011). The incorrect positive rate for the TTSCT was 
calculated as 6.52% (n=3), and the incorrect negative rate 
was calculated as 8.69% (n=4). 

In comparison, the incorrect positive and incorrect 
negative rates for the post-test were calculated as 4.35% 
(n=2). The fact that the false negative, incorrect positive, 
and knowledge deficiency percentages of the TTSCT were 
estimated to be below the limit value of 10% indicates that 
the test is reliable (Hesteness & Halloun, 1995). The 
Cronbach's alpha values calculated for the reliability of the 
TTSCT were 0.642 for S1 scores and 0.52 for M3 scores. 
Moreover, item-total correlations were examined, 
questions with negative correlations were removed from 
the test, and 15 items were obtained. The questions of the 
test were viewed by two academicians, experts in science 
education.  

For the test's structure validity, the correlation between 
the correct answers of the first two tiers, and the case of 

Table 4 Misconceptions of PSTs based on their pre and post-test Misconception-3 scores about the concept of matter 

Misconceptions Pre Post 

Matter 

M1. Mass is the name given to the weight of matter. 17% 9% 
M22. Weight is the name given to an object’s mass. 17% 9% 

M3. An object’s mass decreases on the moon in comparison to its mass on the Earth. 28% 20% 

M4. Weight is measured using balance scales. 74% 52% 

S1. We hear thunder after lightning strikes as a result of the sound’s reverberating. 24% 9% 

S2. We cause the sound to be thinner when we decrease a radio’s sound volume. 
4% 0% 

S3. A portion of the sound is lost when sound volume is decreased. 39% 4% 

 
Table 5 Misconceptions of PSTs based on their pre and post-test Misconception-3 scores about the concept of environment 

Environment 

G1. Global warming causes the ozone layer to decrease in thickness. 33% 24% 

G2. Global warming means that the Earth’s temperature is the same in every part of the world. 0% 2% 

G3. Reducing CO2 amounts will not impact global warming. 26% 4% 

L1. Whales are members of the fish family. 24% 13% 

L2. Seals are members of the fish family. 17% 4% 

L3. Plants feed on their roots. 67% 57% 

L4. Plants obtain their substance by breathing. 7% 4% 

L5. Penguins are mammals. 22% 9% 

L6. Penguins are members of the frog family. 2% 2% 

L7. Penguins are members of the fish family. 13% 4% 

 
Table 6 Misconceptions of PSTs based on their pre and post-test Misconception-3 scores about the concept of space 

Space 

SP1. The moon is the largest object in space. 24% 2% 

SP2. The Earth is larger than the sun and the moon. 13% 2% 

SP3. The Milky Way Galaxy is bound to the sun. 24% 2% 

SP4. Jupiter is a large star. 0% 2% 

SP5. There is air in space. 41% 24% 

SP6. The moon’s size changes depending on its phase. 13% 0% 

SP7. The moon does not revolve around the sun. 13% 11% 

SP8. The moon does not revolve around itself. 24% 15% 

SP9. Earth is the largest planet. 17% 0% 

SP10. The sun’s gravitation pull is stronger during high tide. 30% 9% 

 



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certainty for the third tier (reliability level) was examined. 
The correlation coefficient was calculated as 0.222 for S2, 
at a 0.01 significance level. When the PSTs' scores 
increased at the second tier, an increase in reliability levels 
was also observed. It means that the student teachers gave 
correct answers, and they were also sure of their responses. 
A low relationship between the misconceptions and 
reliability level means that student teachers had 
misconceptions, and they were not entirely sure of their 
answers. 

Furthermore, the observation notes, which were 
another measurement tool, were supported with the 
statements obtained in the data collected from the written 
documents. While these statements were being made, 
codings in PST1, PST13, and PST16 were used. 

 

3. RESULT 
Table 2 represents the dependent t-test for the 

differences between PSTs' pre and post-test Success-1, 2, 
and 3 scores. In Table 2, significant differences were found 
between pre-and post-test scores at all three stages of the 
three-tier test (Success-1, 2, and 3). It was revealed that all 
scores related to success were increased after treatment. It 
was also determined that the rate of correct answers given 
to the question in the first stage of the three-tier test was 
higher than the appropriate steps regarding the explanation 
of the answer and whether or not to be sure about the 
answer. Although tiers scores increased, average pre-and 
post-test success scores decreased. It is thought that the 
practices carried out throughout the research process 

positively affect the success of pre-service teachers in 
related science subjects. 

In Table 3, when the pre-service teachers' 
misconception scores obtained from all three stages of the 
test are examined (Misconceptions-1, 2, and 3 scores), 
significant differences were found between pre and post-
test scores. Average misconception scores decreased for all 
three-tier of the test after the experimental process. It is 
thought that the practices carried out throughout the 
research process are useful in overcoming the pre-service 
teachers' misconceptions in related science subjects. 

In the following tables, misconceptions were presented 
coding as Mass (M), Sound (S), living organisms (L), Global 
Warming (G), Space (SP). Although some misconceptions 
(M3, M4, G1, L3, SP5, SP8) were decreased in the post-
test, some misconceptions were resistant to change and not 
eliminated. This finding obtained from the research will be 
explained with the observation data in the next title. 

As seen in Table 4, although the ratios of the 
misconceptions of PST decreased in the post-test, the 
misunderstanding about the matter was still higher.  The 
effectiveness of the synectic technique is also tricky for 
application in the class because of this result. 

Pre: PSTs' misconceptions on the pre-test Post: PSTs' 
misconceptions on the post-test. As shown in Table 5, the 
percentages of the misconceptions were low in the post-
test, but the statement's ratio as "Plants obtain their 
substance from the soil via their roots" was still high. This 
belief is quite common among the students from primary 
school to university, so it may be resistant to change. Their 
thoughts may back to old after the instruction. As 
presented in Table 6, the ratios of the misconceptions 
about space were low in the post-test. 

3.1. Observational Results About the Teaching Process 
PSTs' misconceptions were observed during class 

activities. During concept cartoon activities, PSTs were 
observed to confuse mass and weight concepts and had 
problems with measurement units. They believed that an 
object's mass on Earth and the moon was the same but had 
trouble describing weight. Some PSTs stated that an 
object's weight in space either changed as it did on the 
moon or decreased. A few PSTs said, "Weight was zero in 
space because there was no gravity in space." PST6 stated 
that "I do not think that matter's mass or weight changes. 
However, there may be gravity, but they still do not 
change." After the cartoon activity concept, PST6 changed 
his idea as "weight was matter's unchanging identity that 
does not change on the Earth or the moon". PST44 stated 
that "Weight changes depending on gravity. It can be 
different in various places of the Earth, and the source of 
gravity is the core. Weight is less at the equator and more 
at the poles. An object's mass does not change; it never 
changes anywhere" after the activity. PSTs wrote stories 
regarding mass and weight from the perspective of a tree 
or an apple. It is a fact that understanding mass, sound, 

 
Figure 2 An example from cartoon completion activity 
(Özdemir, 2006; pp. 19) 
 

 
Figure 1 Example question from the TTSCT 
 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i1.24672 47 J.Sci.Learn.2020.4(1).41-49 
 

global warming, and living organisms poses challenges for 
students at different educational levels. Because of reasons 
such as complexity of the concept, teaching method, and 
textbook, students memorize the science concepts without 
deeper understanding at the primary level. This limited 
understanding of students causes negative feelings to 
science learning, and students carry these learning 
problems to the next school level. 

PSTs were also observed to confuse reverberation and 
speed of sound. One group designed creative drama for 
teaching the statement that “thunder is heard after lighting 
is seen”. Figure 2 shows an example from the cartoon 
completion activities of groups. It revealed their beliefs that 
sound could be transmitted in space and that the characters 
needed to speak louder. 

For eliciting misconceptions of PSTs about living 
organisms, semantic network activity was planned. They 
were given pictures of living organisms to prepare their 
semantic networks. Before the activity, they were observed 
that they had learning problems of classification of living 
organisms. Figure 3 shows examples of semantic networks 
prepared by two PSTs before the application. The figure 
divided living organisms into plants and animals or 
organisms that live in water, organisms that live on land, 
and reptiles.  

Figure 3 reveals that although they still exhibited 
incorrect understandings, PSTs could categorize living 
organisms much more accurately than previously. PSTs 
also mentioned microscopic organisms and mushrooms 
and gave correct examples of flowering and non-flowering 
plants and vertebrates and invertebrates.  

PSTs were observed to have problems conceptualizing 
the solar system, the essential characteristics of planets, the 
sun, Earth, and moon's size and the relationship between 

space and the atmosphere under the theme space. PSTs 
were shown a cartoon film about planets. Following the 
film, faulty parts of the film were asked and discussed. PSTs 
were also asked to write an acrostic poem. One PST's 
acrostic poem for Venus, for example, highlighted that it 
was known as the Earth's twin and mentioned that it was 
the hottest of all planets. They also completed the cartoons. 
Figure 4 represents an example of the cartoons that PSTs 
completed. The study's main conclusions may be presented 
in a short Conclusions section, which may stand alone or 
form a subsection of a Discussion or Results and 
Discussion section.  

Figure 4 reveals that PST39 was aware that Mercury was 
the closest planet to the sun and that both day and night on 
this planet were scorching. In other cartoons, PSTs were 
found to have learned that Venus had dense clouds of 
sulfuric acid, that Jupiter could be seen with the naked eye, 
and that the surface of Mars was red because of iron oxide. 
PSTs also learned the correct order of planets by size.  

The observation records showed that PSTs were made 
aware of their misconceptions and adopted correct 
thinking frames by using various active teaching 
techniques. After the treatment process, it was observed 
that PSTs had fewer misunderstandings and to be able to 
adapt newly acquired scientific information to new 
situations they encountered. 

 

4. DISCUSSION 
The aim of using different active teaching methods is to 

affect academic achievement and conceptual 
understanding of pre-school. Post-tests' scores revealed 
that PSTs' success scores increased for all three tiers after 
the treatment process. Various teaching techniques and 
approaches (Ayverdi, Asker, Öz Aydın, & Sarıtaş, 2012; 
Buntod, Suksringam, & Singseevo, 2010) were found to 
have a positive impact on students' academic performance. 
These findings from other studies are consistent with the 
findings of this study. The PSTs' post-test average 
misconception scores also showed that their 
misconception scores decreased for all three tiers after the 
experimental process. The test results also revealed that 
PSTs were continuing to have some misconceptions such 
as mass and weight, but their ratios were lower than the 
beginnings. This result supports the idea that some 
misconceptions are persistent to change. The result of this 
research agrees with Koray, Özdemir, and Tatar (2005). 
The concept cartoons that PSTs completed in this study 
were thought to reduce their mass and weight 
misconceptions. 

In contrast, educational games, story writing, and 
synthetic techniques were not sufficiently significant to 
overcome PSTs' misconceptions. Yağbasan and Gülçiçek 
(2003) stated that misunderstandings are not structured 
differently from students' other knowledge, and they are 
included in newly acquired information. Therefore, they 
mentioned the difficulty of eliminating misconceptions. 

 
Figure 3 Examples of PSTs’ first semantic networks 
 

 
Figure 4 Cartoon completion by PST39 
 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i1.24672 48 J.Sci.Learn.2020.4(1).41-49 
 

Considering that pre-service teachers develop their 
misconceptions due to their own experiences and 
observations over a long time, it is an expected result that 
some misconceptions will not be eliminated. In this study, 
the related gains' time may not have been sufficient to 
eliminate the pre-service teachers' misconceptions. 

PSTs had misconceptions regarding sound before the 
implementation. Many other researchers also determined 
similar misconceptions of the students from different 
educational grade levels (Hrepic, 2002; Küçüközer, 2009). 
The post-related gains' times of the PSTs decreased. Using 
concept cartoons, creative problem solving, and role play 
may help overcome the PSTs' misconceptions. In the 
literature, studies are supporting this idea (Atasoy, 
Tekbıyık, & Gülay, 2013; Çalık, Okur, & Taylor, 2011). 

PSTs also had learning problems about the 
classification of living organisms. Türkmen, Çardak, & 
Dikmenli (2005) found that students had incorrect 
knowledge about the diversity and classification of living 
organisms and semantic networks were highly effective in 
eliminating these misconceptions. Kaya (2010) concluded 
that conceptual change texts effectively reduced university 
students' misconceptions about photosynthesis and 
respiration. Techniques like scampers and semantic 
networks were effective in diminishing misconceptions of 
PSTs in this study. 

PSTs also had incorrect knowledge about global 
warming and the greenhouse effect like other students at 
different grade levels (Bal, 2004; Ünlü, Sever, & Akpınar, 
2011). It was observed that they had even corrected several 
of these misconceptions after usage of techniques as 
cooperative learning, conceptual change texts, creative 
problem solving, and six action shoes. 

Data collected on the theme of space revealed that PSTs 
had several misconceptions about the solar system, planets, 
sun, Earth, and moon, and the relationship between space 
and the atmosphere. Specifically, different grade levels of 
students were found to have gaps in their knowledge of 
astronomical concepts (Caballero, Moreira, & Rodriguez, 
2008; Taşcan & Ünal, 2016). The present study found that 
the PSTs' insufficient knowledge was partially filled using 
animation and cartoon films and drama during the 
treatment process. Demirel and Aslan (2014) found that 
concept cartoons effectively eliminated students' 
misconceptions about the solar system held by students. 
Türk, Alemdar, and Kalkan (2012) found that students' 
participation in hands-on learning activities was beneficial 
for meaningful learning of astronomy subjects. Conduction 
of relation between science content and daily life events 
was also useful for students' meaningful learning. On the 
other hand, it was observed that experiment-based 
activities and product design techniques were not 
significant enough to overcome the misconceptions of the 
PSTs. 

 

5. CONCLUSION 
In summary, this study's activities facilitated PSTs' 

learning by giving them the responsibility for their 
education. They also enjoyed the learning process, and this 
increased their learning motivation. Thus, meaningful 
learning may have been achieved. The findings of the 
research of Bulunuz (2012) also support these studies' 
results.  Group working may help get away PSTs' 
boringness in the classroom and reduce their learning 
stress. Representing active teaching techniques and a 
democratic instructional atmosphere, cooperative learning 
may help facilitate instruction and elicit misconceptions. 
Shortly, PSTs constructed their meaning by discussing, 
watching, listening, writing, reading, and making. 

Based on all conclusions, it may be suggested that: pre-
school student teachers had problems learning science 
concepts, and they had misconceptions about science 
concepts. The lecturer should be aware of these 
misconceptions. S/he should be planned lessons by using 
different active teaching methods. Both group and 
individual activities should be used. A democratic learning 
environment should be created. It is remembered that 
misconceptions may be persistent to change. When 
designing similar studies in the future, it is recommended 
to determine these persistent misconceptions and develop 
a treatment process based on these conceptions with 
different activities. 
 

ACKNOWLEDGMENT 
The authors would like to acknowledge and thank the 

student teachers for their participation in the research.  
 

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