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 © 2021 Indonesian Society for Science Educator 113 J.Sci.Learn.2021.4(2).113-122 

 
Received:  28 August 2020 
Revised: 27 November 2020 
Published: 27 January 2021 

 

Comparative Effects of Argumentation and Laboratory Experiments on 
Metacognition, Attitudes, and Science Process Skills of Primary School 
Children 

Jale Kalemkuş1*, Şule Bayraktar2, Sabahattin Çiftçi3 

1Science Education, Kafkas University, Kars, Turkey  
2Science Education, Giresun University, Giresun, Turkey  
3Department of Basic Education, Necmettin Erbakan University, Konya, Turkey 
  
*Corresponding author: jale.kalemkus@yahoo.com 
 

ABSTRACT The purpose of this study is to investigate and compare the effects of laboratory experiments 
and argumentation-based science teaching on science process skills, metacognitive awareness levels, and 
attitudes towards the science of 4th-grade elementary school students. In this study conducted according to 
the quantitative research method, a pre-test and post-test quasi-experimental design was used with two 
experimental groups and a control group. Students from three classes of an elementary school participated in 
the study (N = 98). "Science Process Skills Test," "What Do I Really Think about Science Scale," and 
"Metacognitive Awareness Scale" were employed to collect data for the research. The study results showed 
that the science process skills of the 4th-grade students improved significantly in both experimental groups, 
which were taught by employing experiments and argumentation. Students' metacognitive awareness levels 
and attitudes towards science developed in all three groups.  However, it was observed that the development 
was higher in the groups in which science teaching based on experiments and argumentation-based science 
teaching was performed, compared to the control group. 

Keywords Argumentation, Experiments, Metacognition, Science Process Skills, Science Teaching 

 

1. INTRODUCTION 
Since the development of information technology 

facilitated access to information, today's schools aim to 
help students acquire higher-order skills rather than 
directly giving them the information. The 21st century 
requires individuals to have digital-age literacy, critical 
thinking, creative thinking, effective communication, and 
high efficiency (NCREL, 2003). Therefore, today's 
schools' primary goal is to equip students with these skills 
by making necessary arrangements in educational 
environments by utilizing teaching approaches considered 
useful in acquiring these skills. One of these approaches is 
argumentation-based teaching.  

The importance of experiments is well known, and 
they are preferred by teachers in almost all levels of 
education in science education. However, although it has 
been shown to develop students' higher-order cognitive 

skills, teachers are reluctant to practice argumentation 
(Jimenez-Aleixandre, Rodriguez, & Duschl, 2000; 
Newton, Driver, & Osborne, 1999). Furthermore, 
argumentation is hardly utilized in primary grades. A 
review of research on argumentation shows that although 
a significant amount of research has been done at the 
middle and high school level, the number of studies 
conducted with primary school children is limited (Bağ & 
Çalık, 2017). More studies on the applicability of 
argumentation-based teaching in primary grades are 
needed. Furthermore, comparing the effectiveness of 
experiments and argumentation on particular cognitive 
and affective variables is valuable since the questions of 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i2.27825 114 J.Sci.Learn.2021.4(2).113-122 
 

"Which is more effective?" or "Could one of them be an 
alternative to the other?" will be answered. 

The purpose of this research is to investigate and 
compare the effects of laboratory experiments and 
argumentation-based science teaching on science process 
skills, metacognitive awareness level, and attitudes toward 
science of 4th-grade students. 
1.1. Theoretical Framework 

The argumentation process involves making claims, 
using data to support the claims, warranting the claims 
with scientific evidence, and further backing the warrants 
(Simon, Erduran, & Osborne, 2006). Accordingly, an 
argument is developed when a claim is made, providing 
evidence that supports this claim. (Simon et al., 2006; Van 
Eemeren & Grootendorst, 2004). 

According to Toulmin (2003), an argument is an 
assertion and its accompanying justification. In a simple 
argument, there are three elements: data, claim and 
warrant. Toulmin also provides a more complex argument 
structure consisting of data, claim, backing, warrant, 
rebuttal, and qualifier, as seen in Figure 1. 

Among these elements, data refer to evidence or 
specific information used to support the claim. A claim is 
an assertion that the individual would like to prove. 
Warrants explain the relationship of data with the claim. 
The backing is the generally widely accepted basic 
assumptions that justify strengthening the warrant. 
Qualifiers represent the special cases where the claims are 
correct and the limits of accuracy of the claim. On the 
other hand, Rebuttals represent special cases where the 
claim is not valid (Driver, Newton, & Osborne, 2000; 
Lazarou, 2010; Roberts & Gott, 2010; Simon et al., 2006; 

Von Aufschnaiter, Erduran, Osborne, & Simon, 2008). 
An example covering all Toulmin's argument model 

elements is given in Figure 2 (Kalemkus, Bayraktar, & 
Çiftçi, 2019). 

As an element of scientific language, argumentation is 
essential both in the creation and transmission of 
scientific knowledge (Jimenez-Alexiandre et al., 2000). 
Considering that argumentation is one of the dimensions 
of acculturation in scientific discourse, it should be 
encouraged in science education (Jimenez-Aleixandre & 
Erduran, 2007). By developing arguments and evaluating 
others' arguments, students can build an understanding of 
how scientific knowledge is created (Driver et al., 2000). 

 
Figure 1 Toulmin's argument model (Toulmin, 2003: 
97) 

 
Figure 2 An example covering all the elements of Toulmin's argument model 
 



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Inclusion of argumentation in the teaching process 
supports students' critical thinking skills, improves their 
knowledge, thoughts, and judgment, and increases their 
ability to use scientific language (Osborne, Erduran, 
Simon, & Monk, 2001). 

According to Driver et al. (2000), argumentation in 
science classes can help students understand the social 
dimension of science, improve their understanding of 
science's epistemology, and develop conceptual 
understanding and research skills. Students find a chance 
to compare their ideas and others' on a particular topic 
during the argumentation process. In a condition that 
their ideas contradict others, they evaluate the others' 
claims based on the supporting evidence. Suppose the 
supporting data, warrants, and backings are sufficient. In 
that case, students realize that their previous conceptions 
are not acceptable and reorganize their conceptual 
framework to accommodate the new knowledge, 
indicating that conceptual change occurs. 

The fact that science generally includes abstract 
concepts, using teaching methods based on active learning 
seems to be mandatory. Laboratory experiments are 
essential in science education since they engage students 
with hands-on learning experiences (Özdener, 2005). 
Experiments could be defined as actions carried out in an 
appropriate environment with the necessary tools and 
equipment to demonstrate a known fact or test a 
hypothesis. In a learning environment based on laboratory 
experiments, students will have the opportunity of 
establishing a cause-effect relationship for the phenomena 
they encounter, identifying the problem and thinking 
about both causes and solutions of this problem, 
designing experiments to implement the solutions they 
thought of, and performing these experiments to draw 
conclusions based on the data they collected. 

Using experiments, students would have a chance to 
know the world of scientists. Students, who observe their 
teacher or peers while constructing and testing a 
hypothesis, might develop a tendency to construct their 
hypotheses and test them. While testing the hypothesis, 
students think about variables that might affect the result, 
collect data, and reach the result by evaluating the data 
obtained. In this way, the students acquire higher-level 
cognitive skills by establishing a cause-effect relationship. 
If the students' hypothesis is not valid, they enter a 
different thinking process and feel a need to search for 
different solutions for the problem or reconsider their 
variables. When students need to construct a different 
hypothesis about the problem, they refer to social 
communication with peers and reach different solutions, 
thoughts, or ideas by interacting with them. Students' 
constructing and testing hypotheses enable them to 
discover the way the knowledge is constructed. In this 
process, where the student is active, learning by doing is 
supported. The students' psychomotor skills are also 

supported by the experiments carried out as the students 
experience the process similar to that of scientists, their 
interest, curiosity, and motivation towards science 
increase. Experiments carried out both in the classroom 
and in the laboratory environment lead students to gain 
the ability to explain the events they encounter in daily life 
using scientific language. Also, through the experiences, 
the knowledge acquired by students becomes more 
concrete. Furthermore, students could relate the 
knowledge with their existing concepts, and meaningful 
learning takes place. 

Science process skills have been defined as a set of 
practical skills for many scientific disciplines and reflect 
the skills scientists use in scientific research (Anagün & 
Yaşar, 2009; Padilla, 1990). Science process skills are 
grouped under two categories: necessary process skills and 
integrated process skills. Basic process skills are 
fundamental for scientific inquiry. Integrated skills, on the 
other hand, are grounded on the necessary skills and more 
complex (Padilla, 1990). Necessary process skills are 
recording data, classifying, measuring, communicating, 
observing, using space-time relationship between number 
and space, estimating (predicting), and drawing 
conclusions. Integrated process skills are: hypothesizing, 
determining/controlling variables, interpreting data, 
designing/conducting experiments, modeling, and 
defining operationally. Many reports on learning science 
emphasized that students should not only gain conceptual 
and quantitative information but also need to develop 
science process skills such as hypothesizing, designing 
experiments and making conclusions based on data and 
observations, and working with other people as a team to 
solve complex and open-ended problems (Etkina, 
Karelina, & Ruibal-Villasenor, 2008; Yang & Heh, 2007). 

Metacognition is defined by Flavell (1976) as the 
information that a person has about their cognitive 
processes and products of these processes. For example; 
If I realize that I have more difficulty in learning A than 
B; If I think I should check again before I conclude that C 
is correct; If I think I should carefully examine each one 
before deciding which one is the best for a multi-choice 
job, this is a metacognitive process (Flavell, 1976). 

Flavell (1979) believes that cognitive monitoring 
interventions occur through interactions between four 
concepts: metacognitive experience, goals/tasks, 
metacognitive knowledge, and strategies/actions. An 
individual acquires metacognitive knowledge as a 
cognitive creature related to humans and their various 
cognitive tasks, goals, actions, and experiences. A child 
who is aware that, unlike his friend, he is better in 
mathematics than essay writing can be given as an 
example of this knowledge. Metacognitive experiences are 
cognitive or affective experiences that accompany and 
relate to any cognitive intervention (Flavell, 1979). It is an 
example of a metacognitive experience to think of the 



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possibility of failure in some attempts to take place or to 
think that the previous attempt was performed very well 
(Flavell, 1979). Aims/tasks represent the goal of cognitive 
intervention. Actions/strategies, on the other hand, 
actions/strategies explain the cognition or behaviors used 
to achieve them (Flavell, 1979). 

An individual's positive or negative emotional 
tendency towards objects, people, places, events, and 
ideas expresses the concept of attitude (İpek & Bayraktar, 
2004). Having a positive attitude towards any lesson 
increases the student's motivation to learn that lesson. 
Thus, academic success can be expected to increase. 
Research by Downing and Filer (1999) and Zeidan and 
Jayosi (2015) reveal a significant positive relationship 
between attitudes and science process skills towards 
science. 
1.2. Literature Review 

A study by Asterhan and Schwarz (2007) examining 
the effect of argumentation on understanding concepts 
related to evolution determined that students participating 
in the argumentation process acquired more knowledge 
and retained the knowledge compared to the control 
group students. It was determined that the control group 
participants either lost their gains or failed to improve 
their conceptual understanding. Von Aufschnaiter et al. 
(2008) examined the argumentation processes and 
cognitive development of secondary school students in 
science and sociology courses. The research results 
determined that the students used their previous 
experiences and knowledge when they participated in the 
argumentation. Besides, students reinforced their existing 
knowledge and could elaborate on science concepts with 
such activities. Kıngır (2011) investigated the effects of 
argumentation-based science learning approach on 
students' understanding of the concepts of chemistry and 
their academic achievement. The study results showed 
that this approach is more effective in understanding 
concepts related to chemical change and mixtures than 
traditional instruction. 

Türkoguz and Cin (2014) concluded that 
argumentation-based teaching utilizing concept cartoons 
was more effective in increasing students' science process 
skills than traditional instruction. Similar results were 
found by Gültepe and Kılıç (2015) for chemistry class. 
Aslan (2016) showed that laboratory applications based 
on argumentation improved students 'science process 
skills, found to be more effective, specifically in the 
students who have a low level of science process skills. 
Furthermore, the attitudes of the students in both groups 
towards the laboratory course increased positively. 
Karakuş and Yalçın (2016), in their meta-analysis study, 
concluded that argumentation-based science teaching has 
a positive and very large scale in terms of both academic 
achievement and science process skills. 

Aydın and Kaptan (2014) determined that the 
students' metacognition and logical thinking skills in the 
group where the lessons were based on argumentation 
were positively affected. The inquiry laboratory's effect on 
the development of metacognitive skills among chemistry 
students was examined by Kipnis and Hofstein (2008). 
During the research activities, it was observed that the 
students used their metacognitive abilities at various 
stages of the research process. Based on these results, the 
researchers stated that inquiry laboratory applications 
could provide students with metacognitive skills 
opportunities. 

Durmuş and Bayraktar (2010) found that both the 
experimental and conceptual change texts were more 
effective in overcoming the misconceptions than 
traditional instruction. Kanlı and Yağbasan (2008) 
investigated the deductive laboratory approach's 
effectiveness and the 7E model-based laboratory 
approach in developing science process skills. Results 
revealed that the science process skills of the students in 
both groups improved. Aydoğdu, Buldur, and Kartal 
(2013) examined the effect of open-ended and closed-
ended experiments on acquiring science process skills. It 
was determined that there was a significant difference in 
the students' primary and integrated science process skills 
in both groups. The researchers stated that it could be 
said that open-ended science experiments based on 
scenarios are more effective in terms of developing 
primary and integrated science process skills than 
laboratory activities performed using closed-ended 
experiments.  

In the study conducted by Celep and Bacanak (2013), 
it was carried out to get teachers' opinions about scientific 
process skills and acquire these skills. As a result of the 
interviews with the teachers; It was determined that they 
believe that the laboratory method, inventive path, 5E 
model, and Guess-Observe-Explain teaching methods are 
useful in gaining scientific process skills. It was also 
determined that teachers believed that question-answer 
technique, brainstorming, discussion, six-hat technique, 
demonstration experiment, open-ended experiment, 
deductive experiment, inductive experiment, project, and 
case study techniques were influential developing 
scientific process skills. In the study conducted by 
Freedman (2001), laboratory programs to increase 
scientific knowledge achievement and develop an attitude 
towards science were examined. As a result of the 
research, it was determined that the students who 
regularly conduct laboratory activities have higher 
scientific knowledge achievement levels than the students 
without laboratory experience. However, it was 
determined that there was no significant difference in 
attitude towards science between the two groups.  

In the study conducted by Çetin and Şahin-Taşkın 
(2015), the effects of verbal feedback effectively given by 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i2.27825 117 J.Sci.Learn.2021.4(2).113-122 
 

the teacher in the learning-teaching process on the 
metacognitive awareness, academic achievement, and 
attitudes of the primary school students were examined. 
At the end of the study, it was determined that the useful 
feedback of the teacher in the learning-teaching process 
significantly affected the students' academic achievement, 
attitudes towards the lesson, and metacognitive 
awareness. 

This research examines the effects of science teaching 
with experiments and argumentation-based science 
teaching on the scientific process skills, metacognitive 
awareness levels, and attitudes toward science in 4th-grade 
primary school students. For this purpose, answers to the 
following questions were sought: 

1. What is the effect of science teaching with 
experiments on primary school 4th-grade students' 
scientific process skills, metacognitive awareness, and 
attitudes towards science? 

2. What is the effect of argumentation-based science 
teaching on primary school 4th-grade students' scientific 
process skills, metacognitive awareness, and attitudes 
towards science? 

3. What is the effect of science teaching conducted 
with the current curriculum on primary school 4th-grade 
students' scientific process skills, metacognitive 
awareness, and attitudes towards science? 

4. Do the effects of science teaching with experiments, 
argumentation-based science teaching, and science 
teaching carried out according to the current curriculum 
on the scientific process skills, metacognitive awareness, 
and attitudes towards the science of primary school 4th-
grade students differ? 
 
2. METHOD  
2.1. Research Design 

This study adopted a pre-test and post-test quasi-
experimental design with two experimental groups and 
one control group. To separately evaluate the effects of 
argumentation-based science teaching and experimental 
science teaching on variables (metacognitive awareness, 

scientific process skills, and attitude towards science) and 
to make a comparison between argumentation-based 
teaching and experimental teaching, research was 
conducted in two different experimental groups. The first 
experimental group (E1) was taught by utilizing 
experiments, the second experimental group (E2) was 
taught by utilizing argumentation activities, and the 
control group was taught by following the current 
curriculum. 
2.2. Research Group  

The research was carried out with 98 elementary 
school students studying 4th grade of a public school in 
Kars, Turkey. The first experimental group (E1) consisted 
of 29 students (15 girls, 14 boys), the second experimental 
group (E2) consisted of 34 students (17 girls, 17 boys), 
and the control group consisted of 35 students (12 girls, 
23 boys). 
2.3. Data Collection Instrument 

"What I really think of science" Scale: "What I really 
think of science" Scale consisting of 21 Items, developed 
by Pell and Jarvis (2001) and adapted into Turkish by 
Kırıkkaya (2011), was used to determine students' 
attitudes towards science. Cronbach Alpha coefficient was 
calculated for this study as 0.794. 

Metacognitive Awareness Inventory for Children: 
Metacognitive Awareness Inventory for Children (MAI-
C), which was developed by Sperling, Howard, Miller, and 
Murphy (2002) to measure the metacognitive skills of 
3rd–5th-grade students, and adapted into Turkish by 
Karakelle and Saraç (2007), was used to determine the 
metacognitive awareness levels of primary school 4th-
grade students. In this study, the Cronbach Alpha 
coefficient was calculated as 0.89. 

Science Process Skills Test: To determine the science 
process skills of 4th-grade students and to evaluate the 
developments in these skills, multiple-choice test items for 
measuring classification, measurement, observation, 
collecting data, space/time relation, prediction, 
determining variables, interpreting data, drawing a 
conclusion, hypothesis, modeling, and designing 

Table 1 Pre-test scores on the data collection tools by participant groups (ANOVA) 

The Data Collection Tools Groups 
Descriptive Statistical ANOVA 

N X Ss F p 
"What I really think of 
science" Scale 

Experiment 1 29 40.45 6.015 0.149 0.862 
Experiment 2 34 39.68 7.619   
Control Group 35 39.63 5.976   

Metacognitive Awareness 
Inventory for Children 

Experiment 1 29 22.97 6.62 0.521 0.596 

Experiment 2 34 24.38 5.609   
Control Group 35 23.37 5.047   

Science Process Skills Test Experiment 1 29 16.14 5.579 0.462 0.632 

Experiment 2 34 15.03 5.26   
Control Group 35 16.17 5.737   

*significant at the level of p<.05 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i2.27825 118 J.Sci.Learn.2021.4(2).113-122 
 

experiment skills were developed by the researchers, 
based on the review of the relevant literature. There are 
27 items in this multiple-choice test. Each item has four 
different options and one correct answer. Two faculty 
members working in science education, three science and 
technology teachers, and two classroom teachers were 
consulted for expert review of the test. After receiving 
expert opinions and making revisions in the test items in 
line with these opinions, the test was applied to 254 
primary school 4th-grade students. At the end of the 
application, scoring was made by giving 1 point to each 
correct answer given by the students to the test items. 
Each wrong answer was given to the students' test items, 
and the items left blank or marked with more than one 
option were scored by giving 0 points. After scoring for 
each item, item difficulty indexes and item discrimination 
indices of the test items were calculated. The test items' 
discrimination indexes ranged between 0.34 and 0.77, and 
item difficulty indexes varied between 0.28 and 0.85. The 
KR-20 reliability coefficient of the test was calculated as 
0.82. 
2.4. Data Collection Process 

The research was carried out during the instruction 
period of the "Let's Know the Matter" Unit of the science 
class for 4th-grade students and was completed in thirteen 
weeks, including pre-test and post-test studies. In the first 
experimental group (E1), closed-ended and open-ended 
experiments were carried out with group and 
demonstration experiments. The experiments were 
planned together with the first experimental group 
teacher, and the necessary tools and equipment were 
provided in advance (see Appendix A for a sample). In 
the second experimental group (E2), various 
argumentation activities such as competing theories with 
concept cartoons, expressions tables, and experiment 
reports were used for the instruction (see Appendix B for 
a sample).  No intervention was made to the lessons in 
the control group, but it was carried out by following the 
current curriculum with approaches other than 
experiments and argumentation methods. 

2.5. Data Analysis  
One Way Analysis of Variance (ANOVA) was used to 

test whether there are significant differences among E1, 
E2, and Control group students, concerning 
Metacognitive Awareness Scale, Science Process Skills 
Test, and "What I really think of science" Scale for both 
pre-test and post-test. 

 
3. RESULT 

The ANOVA test results to determine whether 
statistically significant differences existed among the 
groups regarding the scores on the data collection 
instruments before the intervention are shown in Table 1. 

As seen in Table 1, the ANOVA test results showed 
no statistically significant difference among the three 
different groups regarding attitudes, metacognitive 
awareness, and science process skills. 

The post-test mean scores for the students in the E1, 
E2, and control group on the "What I really think of 
science" Scale, Metacognitive Awareness Inventory for 
Children, and Science Process Skills Test post-test are 
shown in Table 2. ANOVA test results revealed that there 
were statistically significant differences among the groups 
for all three tests. Scheffe test was used to determine 
which groups caused the difference. 

According to the results of the Scheffe Test at Table 3 
for "What I really think of science" Scale, "Metacognitive 
Awareness Inventory for Children Inventory", and 
"Science Process Skills Test" scores of the participant 
groups showed that the significant differences were 
between the students in both experimental groups and the 
control group (p<.05). There was not a significant 
difference between the scores of the two experimental 
groups. 
 
4. DISCUSSION 

This research was conducted to investigate the effects 
of laboratory experiments and argumentation-based 
science teaching on 4th-grade students' science process 
skills, meta-cognitive awareness levels, and attitudes 

Table 2 Post-test scores on the data collection tools by participant groups (ANOVA) 

The Data Collection 
Tools 

Group 
Descriptive Statistical ANOVA 

N X Ss F p 
"What I really think of 
science" Scale 

Experiment 1 29 57.14 4.462 39.158 0.000 
Experiment 2 34 54.59 5.411   
Control 35 43.91 8.455   

Metacognitive Awareness 
Inventory for Children 

Experiment 1 29 33.62 1.45 24.05 0.000 

Experiment 2 34 32.94 2.37   
Control 35 27.57 5.95   

Science Process Skills 
Test 

Experiment 1 29 24.48 2.68 19.972 0.000 

Experiment 2 34 23.09 4.18   
Control 35 17.69 6.06   

*significant at the level of p<.05 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i2.27825 119 J.Sci.Learn.2021.4(2).113-122 
 

towards science. Results of the study showed that both 
experiments and argumentation activities were more 
effective than traditional instruction. The studies 
conducted on the experimental method support the 
results obtained in this study. In the study conducted by 
Kanlı and Yağbasan (2008), the 7E model-based 
laboratory approach's effectiveness and the deductive 
laboratory approach in developing scientific process skills 
were examined. At the end of the study, it was determined 
that both the 7E model-centered laboratory approach and 
the deductive laboratory approach improved the students' 
scientific process skills. In the study conducted by Bilen 
and Aydoğdu (2012), the activities prepared based on the 
strategy of "Predict-Observation-Explain" in the general 
biology laboratory were examined by comparing it with 
the validation laboratory approach to the development of 
scientific process skills. For the research, while the 
proposed laboratory approach was carried out with the 
experimental group, the validation laboratory approach 
was applied to the control group. At the end of the 
research, it was observed that there was an improvement 
in the scientific process skills of both the experimental 
group students and the control group students. It was also 
determined that this improvement was more in the 
experimental group.  In environments where laboratory 
experiments occur, students can experience science skills 
such as hypothesizing, designing an experiment to test 
their hypothesis, determining and controlling the 
experiment variables, conducting the experiment, 
observing, classifying, and recording data. When these 
opportunities are provided, it will be possible to expect 

for the students to develop their science process skills 
over time. 

When the literature is examined, it is seen that there is 
a study that examines the effect of the experimental 
method on metacognition. This study was conducted by 
Ulu and Bayram (2014). This study investigated whether 
the laboratory applications in the Science and Technology 
course with activities based on the science writing tool 
cause a difference in terms of metacognitive knowledge 
and skills. At the end of the research, there was a 
significant difference in favor of the experimental group 
in terms of explanatory knowledge, methodological 
knowledge, conditional knowledge, planning, and 
cognitive strategy dimensions of the students' 
metacognitive knowledge and skills. Still, there was no 
difference between the experimental and control groups 
in terms of self-control, self-assessment, and self-
monitoring. Students may not feel a need to overthink 
their self-learning when they are passive receivers of 
information. However, they can follow their self-learning 
processes when they are given opportunities to be more 
active. Therefore, the development of metacognitive 
awareness is expectable in an environment that includes 
experimental activities. 

Previous studies determined a positive relationship 
between attitude and science process skills.  One of these 
studies was done by Downing and Filer (1999). In the 
study, the relationship between teacher candidates' 
scientific process skills and their attitudes towards science 
was examined. At the end of the study, it was determined 
that there is a significant positive relationship between 
primary school teacher candidates' science process skills 

Table 3 Scheffe test 

The Data Collection 
Tools 

Group (I) Group (J) 
Variationin 
Average  
(I-J) 

Standard Error p 

"What I really think of 
science" Scale 

Experiment 1 Experiment 2 2.550 1.631 0.299 
Control 13.224* 1.620 0.000 

Experiment 2 Experiment 1 -2.550 1.631 0.299 
Control 10.674* 1.554 0.000 

Control Experiment 1 -13.224* 1.620 0.000 
Experiment 2 -10.674* 1.554 0.000 

Metacognitive 
Awareness Inventory 
for Children 

Experiment 1 Experiment 2 0.680 0.987 0.790 
Control 6.049* 0.981 0.000 

Experiment 2 Experiment 1 -0.680 0.987 0.790 
Control 5.370* 0.941 0.000 

Control Experiment 1 -6.049* 0.981 0.000 
Experiment 2 -5.370* 0.941 0.000 

Scientific Process Skills 
Test 

Experiment 1 Experiment 2 1.395 1.168 0.493 
Control 6.797* 1.160 0.000 

Experiment 2 Experiment 1 -1.395 1.168 0.493 
Control 5.403* 1.112 0.000 

Control Experiment 1 -6.797* 1.160 0.000 
Experiment 2 -5.403* 1.112 0.000 

*significant at the level of p<.05 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i2.27825 120 J.Sci.Learn.2021.4(2).113-122 
 

and their attitudes towards science. Another research was 
conducted by Zeidan and Jayosi (2015). In the study, the 
relationship between students' attitudes towards science 
and their scientific process skills was examined. At the 
end of the study, it was determined that there is a 
significant positive relationship between scientific process 
skills and attitude towards science. Based on this finding, 
it is possible to link the development of attitudes towards 
students' science to develop science process skills. 
Additionally, experiments in teaching environments lead 
students to a position where they could create knowledge 
by being physically and mentally active rather than passive 
receivers of information. When students become active in 
teaching environments, they feel the lesson is fun and 
develops positive attitudes. 

Results of this study revealed that argumentation-
based science teaching also has a positive effect on 
science process skills.  Previous research results support 
this result. In the study conducted by Çınar and Bayraktar 
(2013), the effect of argumentation-based science teaching 
on students' scientific process skills was examined. It was 
determined that the students' scientific process skills in 
the group in which the argumentation-based science 
teaching was carried out were statistically significantly 
higher than the students in the group where the current 
teaching was applied. In the study conducted by Türkoguz 
and Cin (2014), the effect of argumentation based on 
concept cartoons activities on students' scientific process 
skills was examined. At the end of the study, it was 
determined that the students' scientific process skills in 
the experimental group in which argumentation-based 
teaching based on concept cartoons was carried out 
developed more than the control group students. In the 
study conducted by Gültepe and Kılıç (2015), the effect of 
scientific argumentation on students' scientific process 
skills in chemistry teaching was examined. As a result of 
the research, it was determined that both the traditional 
teaching approach and the argumentation-based teaching 
approach improved students 'scientific process skills. 
Simultaneously, it was determined that argumentation-
based teaching was more effective than the traditional 
teaching approach in developing students' scientific 
process skills. In the study conducted by Aslan (2016), the 
effect of argumentation-based laboratory applications on 
scientific process skills and attitude towards laboratory 
course was examined. At the end of the study, it was 
determined that argumentation-based laboratory 
applications improve students' scientific process skills and 
more effective in developing students' skills with lower 
scientific process skill levels. It was determined that the 
students' attitudes in both groups towards the laboratory 
course increased positively with the application. Through 
argumentation, students are involved in the process of 
making claims. To support a claim, they need to access 
some data, make observations, design and apply 

experiments, record the data, and interpret it. Besides, 
students have to determine the variables that will affect 
their claims to determine their claims' limitations and 
refutations. Students feel the need to use these skills for 
their claims and evaluate others' claims. Through 
argumentation activities, students use science process 
skills in experimental teaching, which will improve these 
skills over time. 

 In the study conducted by Aydın and Kaptan (2014), 
argumentation on the metacognition and logical thinking 
skills in teacher candidates' education was examined. At 
the end of the research, it was determined that the 
students' metacognitive and logical thinking skills in the 
group where the lessons were conducted based on 
argumentation were positively affected. In the study 
conducted by Erenler (2017), the effect of argument-
based inquiry research applications on pre-service 
teachers' metacognitive awareness was examined. At the 
end of the study, it was determined that the argument-
based inquiry research method applications were 
statistically significant in all sub-dimensions of 
metacognitive awareness. In the study conducted by Ulu 
(2019), the argumentation-based science learning 
approach on students' metacognitive knowledge and skills 
was investigated. Laboratory activities were carried out in 
the control group based on the traditional approach, in 
the experiment-1 group based on the open inquiry-based 
argumentation-based science learning approach, in the 
experiment-2 group, based on the guided inquiry-based 
argumentation-based science learning approach. At the 
end of the study, two results were obtained. The first of 
these is that argumentation-based science learning-based 
laboratory applications are more successful than 
traditional-based laboratory applications in increasing 
students' metacognitive knowledge and skills. The other 
result is that the guided inquiry-based Argumentation-
based science learning laboratory applications in 
increasing students' metacognitive knowledge and skills 
are more successful than the open inquiry-based 
argumentation-based science learning laboratory 
applications. Argumentation practices might lead students 
to evaluate their self-learning. It is possible for the student 
to question his or her learning, claiming "I learned" or I 
did not learn" and evaluate the argument in the light of 
the supporting evidence similar to the questioning process 
of evaluating whether a claim is true or false in the 
context of the subjects they learn. Individuals' ideas or 
evaluations of their learning are related to meta-cognition. 
Therefore, it is possible to conclude that argumentation 
activities will increase students' metacognitive awareness 
levels. 

 It was determined that argumentation positively 
affected students' attitudes, and this result was supported 
by previous research. In the study conducted by Yalçın 
Çelik and Kılıç (2014), the effect of argumentation-based 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v4i2.27825 121 J.Sci.Learn.2021.4(2).113-122 
 

instruction on students' conceptual understanding, 
attitude towards chemistry, and argumentation tendencies 
was examined. At the end of the study, it was determined 
that the students studying with argumentation had 
significantly higher levels of conceptual understanding, 
attitude towards chemistry, and argumentation tendency 
than the students studying with the traditional teaching 
method. Through argumentation activities, students enter 
making and strengthening their claims and assessing the 
contradictory claims. A learning environment in which the 
student is active is expected to positively affect the 
lesson's attitude towards the lesson. Therefore, 
argumentation activities will also have a positive effect on 
attitudes. 

Control group students' scores on "What I really think 
of science Scale" and "Meta-cognitive Awareness 
Inventory for Children" and "Science Process Skills Test" 
were also increased during this study; however, this 
increase was low in science process skills. This result 
suggests that the current curriculum also positively affects 
metacognitive awareness levels and attitudes towards 
science. The low increase in science process skills might 
result from their not engaged with experiments during the 
study period. 

 
5. CONCLUSION 

This study showed that laboratory experiments and 
argumentation were useful in developing metacognitive 
awareness, science process skills, and attitudes. 
Considering the positive effects of argumentation on 
students, teachers might be encouraged to teach science 
classes based on argumentation when the experiments 
cannot be used. In other words, argumentation-based 
teaching can be preferred as an alternative to the 
experimental method. For teachers to utilize 
argumentation-based teaching, they should be familiar 
with argumentation-based teaching activities and then be 
able to create their argumentation activities. Teachers also 
need to gain awareness regarding the effects of 
metacognition on the learning process. This way, they can 
motivate their students to think about their self-learning, 
leading to improved learning outcomes. 

Teachers' awareness of the positive effects of 
experiments and argumentation should be developed 
considering the results of this study and the previous 
studies on the subject. Laboratory conditions in schools 
should be improved to comply with today's technological 
developments, and the use of these laboratories should be 
encouraged. Especially in elementary school science 
lessons, students should be actively involved in the 
thinking process by including experimental practices and 
simple equipment types. In this process, students should 
be given time for making observations,  thinking about a 
situation,  offering solutions,  evaluating the offered 

solutions, and, if needed, developing or changing these 
solutions, and they should be motivated for this. 
 
ACKNOWLEDGMENT 

This study is a part of the first author's doctoral thesis. 
 

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