Universitas Muhammadiyah Malang, East Java, Indonesia 

 

JPBI (Jurnal Pendidikan Biologi Indonesia) 
 

p-ISSN 2442-3750, e-ISSN 2537-6204 // Vol. 5 No. 1 March 2019, pp. 51-60 

 

 

        10.22219/jpbi.v5i1.7287                                http://ejournal.umm.ac.id/index.php/jpbi                     jpbi@umm.ac.id  51 

Research Article 

Developing guided inquiry-based ecosystem module to 
improve students’ critical thinking skills 
 

Irwan a,1,*, Maridi b,2, Sri Dwiastuti b,3  
a Master of Science Education, Faculty of Education, Sebelas Maret University, Jl. Ir. Sutami No. 36A, Surakarta, Central Java, 57126, Indonesia 
b Science Education Study Program, Faculty of Education, Sebelas Maret University, Jl. Ir. Sutami No. 36A, Surakarta, Central Java, 57126, Indonesia 
1 irwanforsmk@yahoo.co.id*; 2 maridi_uns@yahoo.co.id; 3 dwiastuti54@gmail.com 

* corresponding author 

 

INTRODUCTION  

Critical thinking skill is one of the vital components (de Bie, Wilhelm, and van der Meij, 2015) and an 
important element in the 21st-Century (Nusarastriya, Sapriya, Wahab, & Budimansyah, 2013). Critical thinking 
skill has also become a serious discussion between educators and psychologists about the factors influencing 
in the students (Abdi, 2012). Critical thinking skill is quite important for students since it enables the assume, 
analyze arguments, and evaluate the quality of information (Bensley & Spero, 2014). Critical thinking is a 
cognitive strategy and a way of looking at things and descriptive terms for a set of methods that are used to 
consider and solve problems effectively (Ismail, Harun, Zakaria, & Salleh, 2017; Onions, 2009).  

Students who have critical thinking skills tend to believe and act according to their reasoning logically and 
systematically based on the information received. Critical thinking skill consists of the ability in analyzing, 

A R T I C L E  I N F O   A B S T R A C T    

 

Article history 
Received December 31, 2018 

Revised January 10, 2019 

Accepted February 23, 2019 

Published March 05, 2019 

 The availability of modules that can develop critical students' thinking skills has not 
been fulfilled. This study aimed to develop and determine the characteristics, feasibility, 
and effectiveness of guided inquiry-based ecosystem modules to improve students' 
critical thinking skills. This R&D research referred to Borg and Gall model with nine 
stages. The research instrument used was a test question sheet adapted from Facione. 
The data gained were analyzed using ANCOVA. The results of the study showed that: 
1) the developed module was characterized with guided inquiry-based syntax and 
critical thinking skills aspect; 2) the module was declared feasible based on the gained 
validity scores i.e. 92.19 (very decent) from material expert, 81.90 (very decent) from 
learning expert, 78.57 (worthy) from linguist, 92.86 (very decent) from learning media 
expert, 92.36 (very decent) from practitioners, and 91.80 (very decent) from limited field 
test; 3) the student critical thinking skills achievement which treated by using the 
module was significantly higher compared to another class (F = 120.52; p-value < 0.05). 
It can be concluded that the developed module was feasible to be used in learning and 
effectively improved students' critical thinking skills.  

 

Copyright © 2019, Irwan et al  

This is an open access article under the CC–BY-SA license 

    

 

 
Keywords 
Critical thinking 

Guided inquiry 

Module 

 

  

 
How to cite:  Irwan, I., Maridi, M., & Dwiastuti, S. (2019).  Developing guided inquiry-based ecosystem module to improve students’ 

critical thinking skills. JPBI (Jurnal Pendidikan Biologi Indonesia), 5 (1), 51-60. doi: https://doi.org/10.22219/jpbi.v5i1. 
7287  

 

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understanding, and evaluating both reasons and information (Adeyemi, 2012; Dwyer, Hogan, & Stewart, 2014; 
Shehab & Nussbaum, 2015) and constitute is part of the cognitive skills consisting of interpretation, analysis, 
inference, evaluation, explanation, and self-regulation (Facione, 1992). 

Critical thinking skill concerns the methods of thinking involving cognitive procedures such as reasoning, 
analyzing and evaluating that pedagogically related to problem-solving and communication (Arslan, 2015; 
Wilkin, 2017) and metacognitive processes covering several other components including skills in analyzing 
arguments, concluding skills through both inductive and deductive reasoning, skills in evaluating, and skills in 
making accurate problem-solving decisions (Lai, 2011; Sarigoz, 2012). Critical thinking skills as art in analyzing 
and evaluating thoughts to improve them (Serrat, 2017).  

The development of students’ critical thinking has been a concern and the primary goal of education in the 
world in the last few decades (Aliakbari & Sadeghdaghighi, 2013; Larsson, 2017; Tabačková, 2015). The 
critical thinking skills development serves an essential role in the world of education and is needed by students 
(Visande, 2014). Teaching critical thinking skills has always been a learning-oriented goal for teachers in all 
disciplines (Thompson, 2011).  

Increasing students' critical thinking skills should be the teachers’ responsibility as stipulated in the Minister 
of Education and Culture of Indonesia regulation number 20 of 2016.  The regulation confirms that students 
should have mastered some skills related both creatively, productively, critically, independently, collaboratively, 
and communicatively thinking and acting. The students who have critical thinking skills will be more easily 
explaining scientific concepts, solving problems, and exploring causal relationships from the occurring events 
around them. The learning process carried out in schools should at least be able to provide training for 
students' thinking skills, considering the significant impact of thinking skills owned by each student increases 
after the learning process takes place.  

Students' critical thinking skills in Indonesia still need to be improved. The results of the Program for 
International Student Assessment (PISA) tests in 2015 showed that the average PISA score of Indonesian 
students was 395.3 on science, reading and mathematics so that Indonesia was ranked 62 out of 70 countries. 
Increasing the value of PISA can be done by improving the quality of education and high order thinking skills of 
students through the implementation of the curriculum 2013 (Sukardjo & Sugiyanta, 2018). The results of the 
preliminary research and information collection in this study used instruments based on aspects of critical 
thinking skills in the matter of evaluating textbooks used in school learning on ecosystem material. The results 
of the analysis of evaluation questions on textbooks in the form of teacher handbooks and student handbooks 
showed that the average percentage in the interpretation aspect was 52.75%, the analysis was 11.75%, the 
inference was 13.75%, the evaluation was 6.5%, the explanation was 10%, and self-regulation was 5.25%. The 
results of the analysis show that the aspects of critical thinking skills used in learning at school are still low so 
that they have not accommodated students in developing their critical thinking skills. 

Efforts that can be made to address the problems are by developing teaching materials. The development 
of teaching materials is one of the criteria that must be possessed by the teacher as stated in the academic 
qualifications and teacher competency standards. The Ministry of National Education of Indonesia stipulates it 
on regulation number 16 of 2007 which states that teachers in the senior high school level education units both 
in the demands of pedagogical and professional competencies are closely related to the teacher's ability to 
developing learning resources and teaching materials. The development of essential teaching materials is 
carried out by teachers. It can design learning to be more effective, efficient, and following the competencies to 
be achieved. Teaching materials can be developed in various ways and forms. One of the available teaching 
materials to be developed is a teaching module. Module development can be one solution to assist schools in 
realizing quality learning. Applying modules in schools can create a better planned, independent, complete, and 
produce clear output of learning activities. Modules are self-learning packages that include a series of learning 
experiences that are planned and designed systematically to help students achieve learning goals (Setiyadi, 
Ismail, & Gani, 2017). A learning module is a self-contained, formally structured learning experience with a 
coherent and explicit set of learning outcomes and assessment criteria (Rufii, 2015). Modules can improve 
critical thinking skills as the results of research by Elisanti, Sajidan, and Prayitno (2018) which states that 
learning to use modules in the learning process is very significant to empower students' critical thinking skills. 

This study aimed to develop and determine the characteristics, feasibility, and effectiveness of guided 
inquiry-based ecosystem modules to improve students' critical thinking skills. Guided inquiry-based learning 
contains learning activities that encourage students to analyze, solve problems based on facts found around 
them (Rusche & Jason, 2011) and involve the participation of students actively in a series of learning 
experiences to find answers to problems that exist around them so that students construct their knowledge. 
Guided inquiry-based learning has a significant and effective in improving students' critical thinking skills 
(Elisanti et al., 2018; Nisa, Koestiari, Habibbulloh, & Jatmiko, 2018; Zabit, 2010). Guided inquiry-based syntax 
namely: orientation, designing inquiry (formulating problems, formulating hypotheses, and collecting data) 



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analyzing data, drawing conclusions, and communicating findings (Gengarelly & Abrams, 2009). Guided 
inquiry-based learning is essential to apply to early-level students so that they use conceptual knowledge and 
their understanding to delve deeper into their ideas in the learning process (Jiun & Nurzatulshima, 2014).  

METHOD 

This research and development using the Borg & Gall procedures were modified in nine stages, i.e. (1) 
research and collecting information, (2) planning, (3) development of early product, (4) design validation, (5) 
main product revision, (6) limited field trial, (7) second product revision, (8) operational field trials, (9) the 
revision of the final product (Gall, Gall, & Borg, 2003). The module’s feasibility is guided by Table 1. 

 
Table 1. Qualification of module feasible 

Score Category 

>80 - 100 Very decent 
>60 - 80 Worthy  
>40 - 60 Quite decent 
>20 - 40 Not feasible 
0 – 20 Very unworthy 

 
The operational field trial was conducted to determine the effectiveness of developed modules. The 

operational field trials using pretest-posttest control group design by McKenney and Reeves (2014) with 
experimental and control class. The operational field subject used was X MIA 3 and X MIA 4 class in Senior 
High School 1 of Karas – Magetan Regency in 2018. The sample was selected by cluster random sampling 
with two classes consisting of 29 students in the experimental class and 30 students in the control class. The 
experimental class was treated by conducting learning using a module based on guided-inquiry, while the 
control class conducted by learning using textbooks.  

The research instruments used was 20 multiple choice questions and 10 essay questions adapted from 
Facione's critical thinking skills aspects which: (1) interpretation, (2) analysis, (3) inference, (4) evaluation, (5) 
explanation, and (6) self-regulation (Facione, 1992). The instruments used in this study have been tested for 
validity and reliability by 30 students. The data analysis used ANCOVA with a significance level 0.05 and 
preceded a prerequisite test, i.e. Shapiro-Wilk normality test and Levene’s homogeneity test. The statistical 
analysis program used SPSS 21 for windows. The score categories of students' critical thinking skills showed in 
Table 2. 

 

Table 2. Score category of students' critical thinking skills 

Score Category  

81.25 < X ≤ 100 
71.50 < X ≤ 81.25 
62.50 < X ≤ 71.50 
43.75 < X ≤ 62.50 

0 < X ≤ 43.75 

Very high 
High 

Moderate 
Low 

Very low 
 

RESULTS AND DISCUSSION 

Stage 1: Research and information gathering 
The results of the analysis indicate that students' level of critical thinking skills is classified as very low 

(34.55). In more detail, five of the six components of critical thinking are in the shallow range (0 < x < 43.75). 
The five components include (1) interpretation, (2) analysis, (3) inference, (4) evaluation, and (5) explanation 
with scores in a sequence of 41.14, 32.70, 25.45, 22.54, and 41.07. Meanwhile, the student self-regulation 
component of 44.42 was classified as low. These results show that the learning process carried out so far has 
not been able to improve students' critical thinking skills. Thus, efforts need to be significantly able to help 
improve critical thinking skills. Critical thinking skills need to be improved because it is very fundamental in 
managing learning skills and empowering students to contribute actively and creatively to life. Students who 
have critical thinking skills are more comfortable to solve problems in their lives. Students' critical thinking skills 
are able to explain causal relationships from events that occur around them (Aizikovitsh-Udi & Cheng, 2015).  
 
Stage 2: Planning 

The planning phase begins with determining learning objectives based on core competencies (or 
kompetensi inti/KI) and basic competencies (or kompetensi dasar/KD). The results of this stage stipulate that 
the material developed in the module is an ecosystem. The material is analyzed and adapted to the curriculum 



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used in the school to determine the level of student achievement after learning occurs. The module matrix 
preparation phase is carried out after the goal setting stage. The focus at this stage is to adjust the activities 
planned in the module according to guided inquiry syntax with aspects of critical thinking skills. 

The next step is to determine the guided inquiry-based module format and the format of learning devices 
that include it. The module format developed includes four sub-topic, i.e. (1) ecosystems and their constituent 
components, (2) interactions between organisms in ecosystems, (3) food chains and food networks, and (4) 
biogeochemical cycles, while the format of learning devices used in structured modules the syllabus and plan 
for implementing the learning that is prepared based on the curriculum applied in the school. 

In addition to these four components, the last step is to determine the procedure for developing modules 
such as determining the subject of research, data collection techniques and all data needed in module 
development starting from initial product design development, product validation, to product testing. 
 
Stage 3: Development of initial product draft 

The module prototype design was developed by referring to the syntax of critical thinking skills. At this 
stage, aspects of developing learning objectives, developing indicators, designing learning activities, and 
evaluating are integrated into the module. The results of this stage are printed module prototypes. 
 
Stage 4: The product draft trial phase 

The module prototype testing phase is carried out by involving several expert validators. Validation carried 
out in the development of this module included material expert validation, expert device learning validation, 
validation of readability by linguists, and media validation and module design. The results of expert validation 
can be seen in Figure 1. The results of module validation indicate that guided inquiry-based products are 
feasible for use in learning. 

 

 
Figure 1. Daigram of the results of module validation by expert 

 
Stage 5: The first product revision 

Improvement suggestions from experts were used as the basis for developing the module. Some 
suggestions and corrections made to the modules developed as presented in Table 3. Based on Table 3, the 
modules need to be improved and refined to minimize conceptual errors. 

 
Table 3. Suggestions provided by expert and correction actions taken 

Material 

Suggestion Correction 

Reading the material in learning activities must 
"implicitly" explain the components of teaching material. 

Revise the reading material in learning activities 1 with a more implicit 
explanation about the teaching material components. 

Make sure the teacher module can play an optimal role 
in controlling student modules. 

Revise the learning activities in the teacher module and student modules 
so that can play an optimal role in controlling the student module. 

Note the suitability of guided inquiry syntax in the 
teacher module and student module. 

Revise the suitability of syntax of guided inquiry learning in teacher 
modules and student modules. 

Learning device 

Suggestion Correction 

Each material indicator must represent to basic 
competency. 

Revise material indicators and make sure represent to basic competency. 

Evaluation of modules must represent to material 
indicators 

Revise the evaluation and make sure it represents material indicators. 



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Module readability 

Suggestion Correction 

Sub-chapter that are made hopeful of spelling. Revise the spelling of sub-chapter. 
The caption in the module does not exist. Write a description of the image contained in the module. 
Examine the writing of word absorption elements with 
standard vocabulary. 

Revise the writing errors of the word absorption elements and standard 
vocabulary. 

Media and module design 

Suggestion Correction 

Writing copyright on the Francis page to remove it Eliminate copyright writing on Francis pages. 
The module cover image must include the source library Lists the source of the image library on the front cover of the module. 
the image in the module so that the source of the library 
and the description of the image are included 

Lists the library sources and captions in the image in the module. 

Describe the general description of the subject matter. Describe a general description of material to in the sub-chapter. 
Give clear instructions on each student's activities. 
 

Provide clear instructions on each student's activities in the student 
activity sheet. 

 
Stage 6: Limited field trial stage 

The limited field-testing phase is carried out to determine aspects of qualitative data from the module 
readability. Testing is done intentionally to find out the various shortcomings contained in the module such as 
typos, typo letters, and errors in image layout and so on. This stage also aims to determine students' 
understanding of the contents of the module. The limited field-testing phase was carried out on education 
practitioners and 16 students who were randomly selected. The results of the limited field trial stage are 
presented in Figure 2. The assessment of educational practitioners is in the range of 80-100, as well as the 
results of student evaluations with a score of 91.80. The results of this limited field trial stage indicate that the 
module is feasible to use. 

 

 
Figure 2. Chart of limited field trial stage results by education practitioner and student 

 
Stage 7: The second product revision 

The second revision is done by correcting and completing the errors and shortcomings of the module. The 
errors and shortcomings of the module are obtained from criticism and suggestions and input from education 
practitioners and students who conduct limited field tests, suggestions and input are then followed up by 
making improvements to the developing module. A summary of suggestions and corrections is presented in 
Table 4 and Table 5. The results of the second revision are used for the development of the next stage to 
produce a guided inquiry-based module that is used in learning to improve students' critical thinking skills. 

 
Stage 8: Operational field trial 

This phase begins with validating the instruments used in the study. The results of testing the validity and 
reliability of the instruments as outlined in Table 6. The results of the validity and reliability tests indicate that the 
test instruments used are valid and reliable because of the value of rcount > rtable. Furthermore, the results of the 
operational field trial stage in the form of assessing students' critical thinking skills were analyzed using 
ANCOVA. The results of the statistical analysis show that the Fcount was 120.52 with a significance level of 0.00 
(α < 0.05). These results indicate that there are significant differences between the experimental classes using 
guided inquiry-based modules with the control class using textbooks in schools. These results indicate that the 
use of guided inquiry-based ecosystem modules is effective in empowering students' critical thinking skills. The 



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difference between the posttest results of students in the experimental class shows that the module developed 
is based on aspects of students' critical thinking skills applied to the ecosystem material. 

 
Table 4. Suggestions provided by education practitioners and corrective actions are taken 

Suggestion Correction 

The writing procedure and placement of the images are noticed and 
the subject matter is expanded again. 

Make corrections to the sequence of writing sentences and 
clarify the image on the module and expand the material. 

Writing scientific names are italicized and enlarged. Make corrections to scientific naming and enlarge images. 

Table 5. Suggestions correction is given by students and corrective actions taken 

Suggestion Correction 

There are a number of errors in writing words in modules that are 
caused by several things, such as typos, font sizes that are not 
diverse, and image sizes that are not large enough to be less 
obvious to students. 

Correcting errors in the intended writing and increasing the 
size of the image to make it more visible to students. 

There are several terms and abbreviations that are still considered 
foreign by students. 

The terms and abbreviations referred to are explained on the 
glossary page contained in the module. 

A less attractive cover image. Change the module's front cover image with more interesting 
images. 

Table 6. Recapitulation of the results of validity and reliability test items 

Q Item N N Item Validity Reliability 

MCQs 30 20 100% 0.873 > 0.361 

Essay 30 10 100% 0.708 > 0.361 

 
Stage 9: Revision of final product 

Based on the operational field-testing phase that has been carried out, the guided inquiry-based ecosystem 
module is deemed feasible to be used as teaching material to improve students' critical thinking skills without 
further revisions or improvements. However, evaluation still needs to be done to improve module quality. The 
evaluation and improvement phase of the module is carried out through the process of disseminating modules 
to education practitioners. The evaluation phase aims to get criticism, suggestions, and input to improve the 
final product to be ready for use by product users. 

The distribution of evaluation sheets was carried out to three middle school biology teachers by providing a 
guided inquiry-based ecosystem module and accompanied by an assessment questionnaire related to the 
content in the module. The results of the teacher's response to the guided inquiry-based ecosystem module are 
presented in Figure 3. The teacher's response to the module obtains the average value included in the 
excellent category. Based on these results it can be concluded that the modules developed are feasible to be 
used in learning activities at the secondary school level. 

 

 
Figure 3. Chart of teacher response to the module developed by the teacher  

 
The guided inquiry-based modules characteristics  

This module is developed based on the principle of independence. Students are conditioned to be able to 
interact with learning materials actively and carry out various learning activities and get feedback about what 
they are learning (Rufii, 2015). The module developed contains (1) clear learning objectives and can describe 
the achievement of KI and KD, (2) learning material that is packaged in specific activity units so that it is easy to 



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learn thoroughly, (3) available examples and illustrations support the clarity of the presentation of learning 
material, (4) there are practice questions and assignments, so make it possible to measure the mastery level of 
student, (5) contextual, the material is presented related to the atmosphere, tasks and context of student 
activities and environments, (6) using communicative and straightforward language, (7) there is a summary, (8) 
there are assessment instruments, (9) there are assessment instruments, (10) there is feedback on student 
assessment, so students know the level of mastery of the material, and (11) there is information about referrals, 
enrichments, and references that support learning material (Nisa et al., 2018; Rusche & Jason, 2011).  
 
Feasibility of guided inquiry-based modules 

The module feasibility to improve students' critical thinking skills were tested through validation by experts. 
The results of the material expert validation obtained an average value of 92.19 (very decent) category. Based 
on these results, it can be concluded that the material presented in the module has been declared feasible to 
apply. The ecosystem material contained in the module meets the criteria and feasibility based on the 
assessment indicators provided by the expert. Assessment indicators consist of several aspects including the 
completeness of the material, the material accuracy, activities that support learning, material upgrading, 
material strength in improving students' scientific competencies, material systematics, and material abilities in 
accommodating students' critical thinking skills. 

The results of the expert device learning validation obtained an average value of 81.90 with very decent 
categories. Based on these results it can be concluded that the learning device developed has been declared 
feasible to be applied in the module. Learning devices designed in the module have met the criteria and 
feasibility based on assessment indicators by experts. Assessment indicators consist of the formulation of 
material indicators, the selection of material, the selection of sources and media, approaches and methods, 
assessment of learning outcomes, question material, presentation of questions, scoring, and aspects of 
students' critical thinking skills. However, the linguist validation obtained a mean value of 78.57 (worthy) 
category. On such a result, the language format and readability presented in the module are proper. Readability 
design of the module developed has been declared feasible and fulfills the criteria based on the indicator of 
inquiry by experts. Assessment indicators consist of the suitability of the language with the level of student 
development, communicative, and coherence and unity of ideas. 

The results of the learning media expert validation obtained an average value of 92.86 with a very decent 
category. Based on these results, it can be concluded that the format of the design and graphics presented in it 
has been declared feasible to be used in the module. The design module has been declared feasible and fulfills 
the criteria based on expert indicators. The assessment indicators consist of public presentation organizations, 
considering the meaning and benefits, involving students, general appearance, information delivery techniques, 
the anatomy of modules developed, and observing the code of ethics and copyright. 

The results of limited field testing for education practitioners obtained an average score of 92.36 with a very 
decent category. Based on these results it can be concluded that the guided inquiry-based ecosystem module 
developed is very feasible to use in classroom learning activities. The results of limited field tests by students 
obtained an average score of 91.80 which was categorized as very good. According to the results, an inquiry-
based ecosystem module developed was declared suitable for use in learning activities. However, the 
effectiveness of the module toward improving students' critical thinking skills in the experimental class was 
83.66 with a very high category and a control class of 69.24 with a moderate category. More specifically the 
average value of students' critical thinking skills in each aspect is presented in Figure 4.  

 
Figure 4. Chart of recapitulation of students' critical thinking skills scores by aspects. 



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Moreover, the results of the preliminary test using the normality and homogeneity tests in the experimental 
class and the control class indicate that the data are spread normally and homogeneously. Based on Table 7, it 
can be concluded that the normality test using the Shapiro-Wilk test showed that the pretest and posttest were 
normally distribute (α > 0.05), while the Levene’s homogeneity test in all classes showed homogeneous pretest 
and posttest because of the significance level (α > 0.05).  

Table 7. Recapitulation of the results of the normality and homogeneity test 

Class Test Type of test Result 

Exp. Norm. Shapiro-Wilk test Sig pretest 0.601; Sig posttest 0.07 
Ctrl. Norm. Shapiro-Wilk test Sig pretest 0.074; Sig posttest 0.446 
All Class Homogeneity Levene’s test Sig pretest 0.903; Sig posttest 0.094 

 
 

. The next test conducted is the ANCOVA to determine the difference in posttest values in the experimental 
class and the control class. Based on Table 8, there is a significant difference between the posttest value 
between the experimental class and the control class (α < 0.05). Guided inquiry-based ecosystem module 
effectiveness in improving students' critical thinking skills is 0.683 or 60% (Waluyo, Prayitno, & Sugiyarto, 
2017). Improving students' critical thinking skills through learning using guided inquiry-based modules in this 
study is in line with research by Prihatin, Prayitno, and Rinanto, (2017) which states that the use of guided 
inquiry-based modules is effective in improving students' critical thinking skills. Guided inquiry-based learning 
activities implemented in modules can direct students to be directly involved in the learning process and 
provide opportunities for them to understand material concepts more deeply and make their critical thinking 
skills better (Wang & Posey, 2011). Moreover, improving critical thinking skills in the learning process helps 
students improve their learning outcomes in the classroom (Bahmani, 2016). 

 

Table 8. ANCOVA test 

Variable F Sig Partial eta Square 

All Class 120.52 0.000 0.683 
 
 

Learning activities using inquiry-guided based ecosystem modules can improve students' critical thinking 
skills because they can train students to engage in active learning by (1) interacting with other fellow students, 
(2) making the learning process more interesting by focusing on direct observations in the field, (3) obtaining 
observational data, and (4) discussing it through presentation activities before the class along with the teacher’s 
guidance. The applied guided inquiry-based learning on the module provides better students’ learning 
outcomes value. Various research results show that the application of guided inquiry-based learning has a 
positive trend especially in learning that emphasizes the active participation of students in thinking and 
concluding (Vlassi & Karaliota, 2013). Critical thinking skills include a person's ability to analyze and evaluate, 
have strong ideas and arguments, think consciously and responsibly (He, Craig, & Wen, 2013). 

Learning activities using guided inquiry-based ecosystem modules motivate students to actively engage in 
learning because they place them as a center of learning activity, students not only learn something but also 
actively discover, do, pay attention/observe, and experience the activity of learning in the guidance of the 
teacher as a motivator and facilitator in learning (Simbolon & Sahyar, 2015). Guided inquiry-based learning 
activities can improve students' critical thinking skills because when the learning process takes place, students 
develop their knowledge by facilitating their brains to think Rajagukguk and Simanjuntak (2015) through 
discovery-based learning and centering on themselves with teacher guidance in the learning process. 

CONCLUSION 

Guided inquiry-based ecosystem modules are developed based on guided inquiry syntax, and aspects of 
critical thinking skills are appropriate to be used in the learning process. The effectiveness of the module 
developed was shown by the results which obtained that there was a significant difference between the critical 
thinking skills of students in the experimental class and the control class. This difference shows that the module 
developed is better at empowering students' critical thinking skills compared to the textbooks used in schools. 

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