Universitas Muhammadiyah Malang, East Java, Indonesia JPBI (Jurnal Pendidikan Biologi Indonesia) p-ISSN 2442-3750, e-ISSN 2537-6204 // Vol. 6 No. 2 July 2020, pp. 243-256 10.22219/jpbi.11456 http://ejournal.umm.ac.id/index.php/jpbi jpbi@umm.ac.id 243 Research Article Empowering students’ critical thinking skills, information literacy and cognitive learning outcome through RBL-TPS model Siti S. Narahaubun a,1, Johanis F. Rehena b,2, Dominggus Rumahlatu b,3,* a Study Program of Biology Education, Postgraduate, Universitas Pattimura, Jl. Dr. Tamaela, Ambon, Maluku 97114, Indonesia b Study Program of Biology Education, Faculty of Teacher Training and Education, Universitas Pattimura, Jl. Ir. M. Putuhena, Ambon, Maluku 97233, Indonesia 1 sitisanianarahaubun@gmail.com ; 2 rehena.jf@gmail.com; 3 dominggus_amq@yahoo.co.id* * Corresponding author INTRODUCTION Education is one of parts that affected by the industrial revolution (Azid, Hasan, Nazarudin, & Md-Ali, 2020; Becker, Hornung, & Woessmann, 2019; Ghozali, 2018). A similar idea is also stated by Benešová and Tupa (2017) that the industrial revolution has a high effect for the education of communities, where several professions will be altered by computer and Industry players must collaborate with universities so that the university graduates are able to answer the challenges of the industrial revolution. Departing from this idea, education is an area that should be given an extra concern in its current development. This is done so that the university graduates produced by higher education have the ability and competitiveness in the world of work. Lasi, Fettke, Kemper, Feld, and Hoffmann (2014) also add that industrial revolution has wide effect, in which it not only influences the A R T I C L E I N F O A B S T R A C T Article history Received March 06, 2020 Revised June 06, 2020 Accepted June 17, 2020 Published July 21, 2020 The use of proper learning model by teachers’ in a classroom is crucial to be done in addressing better learning quality. This study aimed at improving learning quality by choosing the most optimum learning model. This research was a quasi-experimental study using a non-equivalent pre-test-posttest control group design. This study was conducted in Senior High School 9 and Senior High School 5 of Ambon in the academic year 2018/2019.The total sample used in this research was 127 students. The Critical Thinking Skills (CTS) and Cognitive Learning Outcome (CLO) tests as well as information literacy observation sheets were used as the instruments to gain the data. The data obtained in terms of students’ CTS, CLO ang information literacy were analyzed using inferential statistics (ANCOVA and LSD tests). The results showed that there were significant differences among X graders’ CTS, CLO, and information literacy [ F (1,124) = 64.380, F (1,124) = 68.238 F(1,124) = 26.078 , p < 0.05] respectively, who were taught using RBL-TPS learning model in biodiversity material. In the other words, the RBL-TPS learning model is able to empower students’ CTS, CLO, and information literacy compared to the common learning model used by biology teachers. Thus, the used of RBL-TPS is recommended to be implemented in the other biology learning materials. Copyright © 2020, Narahaubun et al This is an open access article under the CC–BY-SA license Keywords Critical thinking skills Cognitive learning outcome Information literacy RBL-TPS How to cite: Narahaubun, S. S., Rehena, J. F., & Rumahlatu, D. (2020). Empowering students’ critical thinking skills, information literacy and cognitive learning outcome through RBL-TPS model. JPBI (Jurnal Pendidikan Biologi Indonesia), 6(2), 243- 256. doi: https://doi.org/10.22219/jpbi.v6i2.11456 http://ejournal.umm.ac.id/ http://u.lipi.go.id/1422867894 http://u.lipi.go.id/1460300524 https://doi.org/10.22219/jpbi.v6i2.11456 http://ejournal.umm.ac.id/index.php/jpbi mailto:jpbi@umm.ac.id mailto:sitisanianarahaubun@gmail.com mailto:rehena.jf@gmail.com http://creativecommons.org/licenses/by-sa/4.0/ https://doi.org/10.22219/jpbi.v6i2.11456 http://creativecommons.org/licenses/by-sa/4.0/ https://crossmark.crossref.org/dialog/?doi=10.22219/jpbi.v6i2.11456&domai JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 244 Narahaubun et al (Empowering students’ critical thinking skills …) industrial production but also labor market and education system. Sharma (2019) asserts that education in the Industrial Revolution 4.0 aims to improve teacher skills and student learning outcomes. Setiyawami, Sugiyo, Sugiyono, and Rahardjo (2019) propose that the impacts of Industrial Revolution 4.0 in education are to improve the students’ skills in any aspects i.e. creativity, critical thinking, problem-solving skill, collaboration, and self- assessment. Kayembe and Nel (2019) also assume that the industrial revolution 4.0 brings many changes to the use of internet for various information literacy. The challenge confronted by biology teachers specifically in Ambon city is in implementing innovative learning to improve the student learning outcomes while developing other skills such as critical thinking and student information literacy. Therefore, biology teachers are still trying to improve the quality of learning so that the students are ready to encounter education 4.0. One way to improve the quality of learning is by deciding on and using the right learning model to empower the students' skills. One of the learning models that is compatible to be implemented in the era of education 4.0 is Resource-Based Learning (RBL) model (Noguez & Neri, 2019). Laverty (2000) emphasizes that the RBL learning model provides an opportunity for the students to look for information about concepts being studied, this can be an investigation of learning sources for the students since the process of seeking information is not only an individual task but it can be done during the learning process. Indeed, according to Vella (1997), the RBL is a learning model which a has wide learning sources and this model provides an opportunity for the students to be an independent learner. If the teachers use the RBL learning model, the teachers are able to direct the students in looking for information from various sources i.e. printed media and even no-printed media. Hill and Hannafin (2001) emphasize that learning sources can be in the form of primary and secondary learning sources. Learning sources which come from people, places, and ideas are called as primary learning sources, whereas learning sources that come from media are called as secondary learning sources. Resource-Based Learning (RBL) is a learning model that successfully develop information literacy skills so that the students are responsible for finding out and using the right material to be studied (Melendres, 2015). Additionally, the RBL learning model also has been combined with several learnings to improve student learning outcomes and learning quality. Febriani, Suratno, and Fikri (2015) combine the RBL learning model with a snowball throwing model, where the experimental class has better cognitive learning outcomes rather than the control class. Qoyyum, Jazim, and Linuhung (2017) report that the students who taught using RBL-Scramble have higher learning outcomes than the students who taught using conventional learning used by the teachers. Yaniwati, Kariadinata, Sari, Pramiarsih, and Mariani (2020) integrate the RBL along with online learning in order to improve the students’ creative skill and self-confidence in mathematics learning. Saridewi, Suryadi, and Hikmah (2017) report that the student learning outcomes increase along with the use of discovery learning methods and learning experiences. In the interim, a study conducted by Ahmed and Khanam (2014) inform that the RBL learning model affects to the student learning outcomes. The student learning outcomes are started by an understanding of a concept. Thru this understanding, the students train their basic thinking skills. The students who have good basic thinking can empower higher-order thinking, one of which is critical thinking. Facione (2010) enlightens critical thinking skills as an interpretation, analysis, conclusion, self-reinforcement skill. Based on Shanti, Sholihah, and Abdullah (2018) and McLaughlin and McGill (2017), critical thinking is a skill in making a rational decision against something that becomes a belief and it is done by the students. Taghva, Rezaei, Ghaderi, and Taghva (2014) emphasize that critical thinking skill also can give contribution on the students’ cognitive ability. The students’ critical skill can also develop since it is also influenced by the information gained by the students thru various sources i.e. through learning, reading digital or printed book, as well as newspaper and digital or printed magazines. Looking for information by means of printed sources and even digital can be interpreted as information literacy. Catts (2012) defines the information literacy as an ability to discover, evaluate, and utilize information to compile new knowledge Catts and Lau (2008) recommend that information literacy skill is developed in conjunction with Information and Communication Technology skills; thus, techniques to access and utilize information and cognitive abilities are needed. In the last few years, several studies in the education field also use the Think-Pair-Share (TPS) learning model to discover the influences in improving the student learning outcomes (Hetika, Farida, & Sari, 2017; Hamdan, 2017; Ogunyebi & Henry, 2018; Rahayu & Suningsih, 2018). Apriani (2016) clarifies that a learning using the TPS learning model can provide the students with plenty of time and attention to formulate individual ideas or thoughts before sharing the concepts studied with other students. Kaddoura (2013) enhances that active learning techniques in the TPS learning model can be used for the development of critical thinking. Other researchers have integrated the TPS learning model along with the Reading Concept Map (Remap) learning model and Guided Discovery which has succeeded in improving the student learning outcomes (Jatmiko, Kartina, Irwandani, Fakhri, Pricilia, & Rahayu, 2018; Bamiro, 2015). Additionally, Setiawati and Corebima (2018) assert that the integration of PQ4R-TPS learning model can improve the students’ critical thinking skill. JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 245 Narahaubun et al (Empowering students’ critical thinking skills …) The integration of the RBL and TPS learning models on science learning in general and particularly in biology has never been done. Consequently, based on several combination studies of learning model that have been conducted previously, this study combines the RBL and TPS model in the material learning of biodiversity. Biodiversity material learns about the concept of the level of biodiversity in genes, species, and ecosystems. In studying these concepts, the students require information literacy skill, after finding out the information, the students will pick out and use the information. Thus, it is required a critical thinking from the students to divide good information and can answer the purpose of study from the teachers. If the information literacy skill and students’ critical thinking have been performed, it will give influence in improving the student learning outcomes. Departing from the explanations above, the combination of RBL-TPS learning models is designed to be able to empower the cognitive, critical thinking, and information literacy skills possessed by the students to learn the material of biodiversity. Therefore, this study aims to discover the influence of RBL-TPS learning model to the student learning outcomes of cognitive, critical thinking, and information literacy skills in studying the biodiversity material. In the future, the results of this study can be used as a basis for study that combines the RBL-TPS learning model. METHOD This study was a quasi-experimental study to discover the influence of RBL-TPS model to the student learning outcomes of cognitive, critical thinking, and information literacy. Design of study used was non-equivalent pre- test-posttest control group design (Table 1). Table 1. Design of study E Y1 X1 Y2 K Y1 X2 Y2 Description: E: experimental group; P: control group; Y1: pre-test; Y2: posttest; X1: STAD learning model; X2: RBL-TPS learning model This study was carried out at SMA 9 Ambon and SMA 5 Ambon in the academic year of 2018/2019. The SMA 5 Ambon represented a school that was ISO certified and accredited A, while the SMA 9 Ambon represented as school that was not ISO certified and accredited B. Population of this study were whole students of 10th grade at SMA Negeri 9 Ambon and SMA 5 Ambon. The samples of this study were detailed as follow; the students of X1- class consisting of 30 students and 29 students of X-2 class, whereas in the SMA 5 Ambon, there were 34 students from X-1 class and 34 students from the X-2 class; moreover, the total students that would be used as samples were 127 students. The sample determination of this study used purposive sampling technique based on the researchers’ consideration that the class used as sample had characteristics based on the purpose of study with the provision that (1) the students were heterogeneous in terms of ethnicity, social, and gender; (2) availability of laptops, cellphones, and tablets to support literacy-based learning. In each school, the students of X-1 class were taught using Student Teams Achievement Divisions (STAD) learning model. The students of X-2 class were taught using the RBL-TPS learning model with similar material, namely biodiversity. This was interpreted that data collection was carried out in four classes, and each class was conducted in 2 meetings. The instruments used were test instruments in the form of essay items to measure the cognitive and critical thinking learning outcomes. However, scoring rubric to assess the cognitive learning outcomes and critical thinking was different. Scoring rubric for cognitive learning outcomes was developed by the researchers and referred to the answers and accompanied by complete, correct, and logical reasons. Scoring rubric of critical thinking emphasized on the criteria that (1) all concepts were correct, clear, and specific; (2) the argumentation was correct, clear, and specific, reinforced by strong reasons; (3) the flow of good thinking and concepts were interrelated; (4) the answer contained good and correct grammar (Zubaidah, Corebima, & Mistianah, 2015). Another instrument used was not-test instrument in the form of observation sheets to assess the students’ information literacy before and after the learning took place. Indicators of observation sheets of information literacy were enthusiasm, discovery, and selection of information, organization of information, use of information and communication (Catts & Lau, 2008). The items were compiled referring to the competency standard based on the provisions of the National Education Standardization Agency (BSNP). JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 246 Narahaubun et al (Empowering students’ critical thinking skills …) The instrument used was first tested for validity and reliability. The validity test was used to determine the validity of each item and the content validator was the supervisor, while the reliability test was used to determine the consistency of the object measured using the Cronbach's Alpha method (Table 2). Table 2. Data reliability test results Cronbach’s Alpha Items Description 0.666 6 Reliable The stages of study for the implementation of learning material for environmental change were carried out almost simultaneously in each class and using different learning tools. The class X-1/control class used the STAD learning model, in which it was a learning in several small groups, doing assignments from the teacher then doing quizzes independently at the end of the lesson. Meanwhile, the class X-2/experimental class used the RBL-TPS learning model. However, the assessment of students' cognitive skil, critical thinking, and information literacy variables remained the same. The stages of data collection in this study used two learning models whose stages were combined to form a new learning model, namely the stages of the RBL-TPS learning model (Table 3). Table 3. Stages of RBL-TPS learning model RBL learning model TPS learning model RBL-TPS learning model 1. Identifying questions or problems 2. Planning how to find out information 3. Gathering information 4. Synthesizing information 5. Evaluating (Febriani et al., 2015) 1. Think: Independent thinking to a question or problem given by the teachers 2. Pair: Pairing up with friends and sharing the results of independent thinking 3. Share: Presenting paired results to the class (Ogunyebi & Henry, 2018) 1. Identifying questions or problems independently 2. Planning how to find out information independently 3. Gathering information independently 4. Synthesizing information independently 5. Synthesizing information in pairs 6. Evaluating Before the implementation of learning began, the pre-test and observation sheets were given to the experimental and control class students. The results of prettest and the results of preliminary information literacy observations were used as covariates to measure the students' cognitive learning outcomes, critical thinking, and information literacy. Posttest and final observation assessment given to the experimental and control class students, carried out after the application of the learning model. The results of the posttest were used to measure the students' cognitive learning outcomes and critical thinking. The final observation sheet was used to assess the students' final literacy. The data were analyzed using descriptive and inferential statistics. Descriptive statistics were used to determine the students' cognitive learning outcomes, critical thinking, and information literacy, where the data were grouped into class intervals and the frequency and percentage were calculated. Inferential statistics used the ANCOVA test to determine the influence of the RBL-TPS learning model on the students' cognitive learning outcomes, critical thinking, and information literacy. The test criteria for the ANCOVA test, namely if the probability or significance is <0.05 (p <0.05), it can be stated that there is an influence between the independent variables on the dependent variable partially, but if the significance is> 0.05 (p> 0.05), then it can be said that there is no significant influence between each independent variable on the dependent variable. Before the ANCOVA analysis was carried out, a prerequisite test was carried out, namely the normality and homogeneity test of the data. Then, the data were analyzed using the SPSS 18.0 program. RESULTS AND DISCUSSION Students’ critical thinking The results of study at SMA 9 Ambon (Table 4) showed that the distribution of critical thinking initial test scores in the control class was in the range of 43-60 (100%), while the students' final test scores were in the JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 247 Narahaubun et al (Empowering students’ critical thinking skills …) range of 62-88 (86.7%). For the students' critical thinking scores in the experimental class, the distribution of scores on the initial test was in the range of 47-58 (100%), while the final test scores were in the range of 60-83 (100%). Furthermore, the results of the study at SMA 5 Ambon (Table 4) indicated that the distribution of students 'critical thinking initial test scores in the control class was in the range of 50-67 (100%) r, while the students' final test scores were in the range of 61-76 (49.6%). For the students' critical thinking scores in the experimental class, the distribution of scores on the initial test was in the range of 47-61 (100%), while the final test scores were in the range of 70-94 (100%). This meant that there is an increase in the score of students' critical thinking before and after the students are taught using conventional learning models and the RBL-TPS learning model at SMA 5 Ambon. Similar condition is shown by Tamara (2018) that there is a difference on the students’ critical thinking before and after the learning using the implementation of learning model. According to Rumahlatu, Sangur, and Liline (2020), the students who taught using CITP learning model are able to develop their critical thinking skills so that it is different from the students who taught using conventional learning model. This is different from a study conducted by Setiawati and Corebima (2018) who postulate that the TPS can be combined with PQ4R, in which it can improve the critical thinking skill. Likewise, a study conducted by Mahardini, Khaerunisa, Wijayanti, and Salimi (2018), It is revealed that the RBL model is able to improve critical thinking skills through authentic learning. The findings of this study indicated that the combination of the RBL-TPS learning model is able to improve the students' critical thinking, since the two syntaxes of the learning model are complementary and provide characteristics that distinguish these two learning models from the combination of other learning models. Table 4. Student’s critical thinking results School/research class Control class Experimental class Pretest Posttest Pretest Posttest Interval F FR (%) Interval F FR (%) Interval F FR (%) Interval F FR (%) SMA 9 Ambon 43-45 3 10 57-61 4 13.3 47-48 1 3.45 60-63 2 6.9 46-48 3 10 62-66 12 40 49-50 9 31 64-67 3 10.3 49-51 9 30 67-71 9 30 51-52 0 0 68-71 7 24.1 52-54 8 26.67 72-76 2 6.67 53-54 14 48.3 72-75 7 24.1 55-57 4 13.33 77-81 2 6.67 55-56 0 0 76-79 7 24.1 58-60 3 10 82-86 1 3.33 57-58 5 17.2 80-83 3 10.3 Total 30 100 30 100 29 100 29 100 SMA 5 Ambon 50-52 12 35.3 53-56 1 2.94 47-49 4 11.8 70-74 6 17.6 53-55 9 26.5 57-60 16 47.1 50-52 9 26.5 75-79 7 20.6 56-58 11 32.4 61-64 6 17.6 53-55 6 17.6 80-84 18 52.9 59-61 1 2.94 65-68 6 17.6 56-58 8 23.5 85-89 1 2.94 62-64 0 0 69-72 2 5.88 59-61 7 20.6 90-94 2 5.88 65-67 1 2.94 73-76 3 8.82 Total 34 100 34 100 34 100 34 100 Students’ information literacy skills The results of study at SMA 9 Ambon (Table 5) showed that the distribution of the initial scores of students' information literacy skills in the control class was in the range of 33-44 (100%), while the final scores of students' information literacy skills were in the range of 83-100 (100%). For the information literacy scores of students in the experimental class, the distribution of the initial scores was in the range of 33-41 (100%), while the final scores were in the range of 83-100 (100%). Additionally, the results of study at SMA 5 Ambon (Table 5) indicated that the distribution of the initial scores of students 'information literacy skills in the control class was in the range of 33-44 (100%), while the final scores of students' information literacy skills were in the range of 83-100. (100%). For the information literacy scores of students in the experimental class, the distribution of the initial scores was in the range of 33-50 (100%), while the final scores were in the range of 83-100 (100%). This meant that there is an increase in the score of students’ information literacy before and after the students are taught using conventional models and the RBL-TPS learning model at SMA 9 Ambon and SMA 5 Ambon. This occurs since the assessment to the information literacy skill affects the student learning outcomes (Saptasari, Sunarmi, Sulasmi, Wicaksono, & Sudraja, 2019), as well as the students’ behavior to the information literacy that significantly affect on the students’ information literacy and their perception about information literacy (Adekunle, Olla, Olajide, Osuji, & Adedoyin, 2019). This is different from a study conducted by Rufiana and Mulyadi (2017) that the TPS learning model can be modified to be TPSS (Think, Pair, Share, and Square) and it can improve the critical thinking, cooperation, listening, and writing. The advantage of the combination of the RBL-TPS JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 248 Narahaubun et al (Empowering students’ critical thinking skills …) learning model is that it can train the students to do information literacy and think independently; then, make pairs and share information with peers. Table 5. Student’s information literacy skill results School/research class Control Class Experimental Class Initial Assessment Final assessment Initial Assessment Final Assessment Interval F FR (%) Interval F FR (%) Interval F FR (%) Interval F FR (%) SMA 9 Ambon 33-35 28 93.3 83-85 9 30 33-35 23 79.3 83-85 2 6.9 36-38 0 0 86-88 0 0 36-38 0 0 86-88 0 0 39-41 1 3.33 89-91 7 23.3 39-41 6 20.7 89-91 9 31.03 42-44 1 3.33 92-94 9 30 92-94 13 44.82 95-97 0 0 95-97 0 0 98-100 5 16.7 98-100 5 17.25 Total 30 100 30 100 29 100 29 100 SMA 5 Ambon 33-35 16 47.1 83-85 2 5.88 33-35 13 38.2 83-85 1 2.94 36-38 0 0 86-88 6 17.6 36-38 0 0 86-88 0 0 39-41 16 47.1 89-91 7 20.6 39-41 13 38.2 89-91 1 2.94 42-44 2 5.88 92-94 0 0 42-44 7 20.6 92-94 11 32.4 95-97 19 55.9 45-47 0 0 95-97 0 0 98-100 34 100 48-50 1 2.94 98-100 21 61.8 Total 34 100 2 5.88 34 100 34 100 Student cognitive learning outcomes The results of the study at SMA 9 Ambon (Table 6) showed that the distribution of the students 'cognitive pre- test scores in the control class was in the range of 40-60 (93.33%), while the students' cognitive posttest were in the range of 64-83 (76.7%). For the students' cognitive scores in the experimental class, the distribution of scores on the pre-test was in the range of 50-67 (100%), while the posttest scores were in the range of 66-95 (86.2%). In addition, the results of the study at SMA 5 Ambon (Table 6) indicated that the distribution of students 'cognitive pre-test scores in the control class was in the range of 30-64 (100%), while the students' posttest scores were in the range of 45-80 (100%). For the students' initial cognitive test scores in the experimental class, the distribution of students' scores on the pre-test was in the range of 50-67 (100%), while the posttest scores were in the range of 70-99 (100%). This meant that there is an increase in student cognitive learning outcomes before and after the students are taught using the STAD model and the RBL-TPS learning model at SMA 9 Ambon and SMA 5 Ambon. However, the increase in learning outcomes before and after the application of the RBL-TPS learning model was higher than the application of the STAD learning model. Table 6. Student cognitive learning outcomes School/research class Control class Experimental class Pretest Posttest Pretest Posttest Interval F FR (%) Interval F FR (%) Interval F FR (%) Interval F FR (%) SMA 9 Ambon 40-44 2 6.67 60-63 7 23.3 50-52 2 6.89 60-65 4 13.8 41-45 3 10 64-67 8 26.7 53-55 3 10.34 66-71 3 10.3 46-50 10 33.33 68-71 9 30 56-58 0 0 72-77 13 44.8 51-55 5 16.67 72-75 2 6.67 59-61 10 34.48 78-83 8 27.6 56-60 8 26.67 76-79 0 0 62-64 0 0 84-89 0 0 61-65 2 6.67 80-83 4 13.3 65-67 14 48.28 90-95 1 3.45 Total 30 100 30 100 29 100 29 100 SMA 5 Ambon 30-35 1 2.941 45-50 6 17.6 50-52 6 17.65 70-74 6 17.6 36-41 0 0 51-56 9 26.5 53-55 3 8.824 75-79 15 44.1 42-47 1 2.941 57-62 6 17.6 56-58 0 0 80-84 5 14.7 48-53 13 38.24 63-68 6 17.6 59-61 14 41.18 85-89 2 5.88 54-59 5 14.71 69-74 6 17.6 62-64 0 0 90-94 3 8.82 60-64 14 41.18 75-80 1 2.94 65-67 11 32.35 95-99 3 8.82 Total 34 100 34 100 34 100 34 100 A study of Siregar, Susilo, and Suwono (2017), also show that the TPS learning which combined with TTW affects to the students’ cognitive learning outcomes. A study conducted by Awaluddin (2019) also reveals that the RBL learning model can improve the student learning outcomes. Thus, the RBL-TPS learning model is more effective in improving the students’ cognitive learning outcomes, since it has special characteristics i.e. learning JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 249 Narahaubun et al (Empowering students’ critical thinking skills …) sources, then independent thinking, pairs and report the results of the paired discussion in class discussion. The RBL-TPS learning model can also activate the students in the learning process. The constructivist learning model can make all students actively involved during the learning process (Rofieq, Latifa, Susetyarini, & Purwatiningsih, 2019). The influence of RBL-TPS learning model to the critical thinking skills, information literacy, and cognitive learning outcomes Prerequisite test After knowing the scores of students’ critical thinking, information literacy, and cognitive, then it was continued to the normality test of data using Kolmogorov-Smirnov test. The results indicated that the data were normally distributed, while the Levene test indicated that the data came from a homogeneous population (Table 7). Table 7. Homogeneity test results and data normality Variables Levene statistic Kolmogorov-Smirnova Score Sig. Level of confidence Description Score Sig. Level of confidence Description Critical thinking .530 .468 α=0.05 Homogen eous 1.257 .085 α=0.05 Normal Information literacy 1.342 .091 1.716 .090 Cognitive learning outcomes 2.113 .149 1.475 .066 Hypothesis test The results of ANCOVA test to the students’ critical thinking after being given a learning using conventional learning model and the RB-TPS learning model, it was shown in the Table 8 and an advanced test of LSD was shown in the Table 9, as the following: Table 8. The results of critical thinking hypothesis test Source Type III sum of squares df Mean square F Sig. Corrected Model 4662.994a 2 2331.497 68.464 .000 Intercept 4199.201 1 4199.201 123.309 .000 kritis_awal 430.079 1 430.079 12.629 .001 model_pembelajaran 2323.817 1 2323.817 68.238 .000 Error 4222.746 124 34.054 Total 628388.889 127 Corrected Total 8885.739 126 Table 9. Advanced test results of critical thinking Learning model Mean LSD notation Conventional 64.1146 a RBL-TPS 75.6614 b The ANCOVA test results (Table 8) showed that the Fvalue was 68,238 with a significant value of 0.00 <0.05. Based on these results, then H0 was rejected and H1 was accepted. This meant that there is an influence of the learning model on students' critical thinking. In addition, the LSD advanced test results (Table 9) showed that there is a notation difference between the conventional learning model used in the control class (notation a) and the RBL-TPS learning model used in the experimental class (notation b). This proved that the students who were taught using the RBL-TPS learning model had better critical thinking skills than the students who were taught using conventional learning models, both at SMA 5 Ambon and SMA 9 Ambon. These findings are reinforced by a statement of Birgili (2015) a learning model using problem-solving activity can improve the students’ critical thinking skills. In the RBL-TPS also emerge a problem-solving activity thru an information discovery and independent thinking and then information sharing to the peers, as well as continued to the JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 250 Narahaubun et al (Empowering students’ critical thinking skills …) second meeting that is biodiversity observation. Meanwhile, in the conventional learning, activities emerge up are discussion and presentation using STAD learning model. Based on Sinprakob and Songkram (2015), critical thinking must be continuously empowered so that it becomes a habit for students' daily lives. The stages in the RBL-TPS learning model are a combination of learning stages that are able to empower critical thinking skills which include a good flow of thinking and able to link various concepts of biodiversity. Rusmansyah, Ibrahim, Isnawati, and Prahani (2019) argue that systematic learning stages help the students to remember the steps to empower critical thinking. The independent information search stage helps the students to practice as critical thinkers to find out and use that information to form a logical flow of thinking. Furthermore, the students are also trained to convey arguments when thinking independently to their partners and when doing the stages of thinking with their partners. The critical thinking stage is also trained in the second meeting, which is when observing the components of biodiversity in the environment, the students will use correct concept of biodiversity and be able to link various types of biodiversity into an understanding. The same opinion is conveyed by Susiani, Salimi, and Hidayah (2018) and Boleng (2015) that critical thinking is a skill to analyze, evaluate, synthesize information from an accurate source, use information properly in the digital era as well. Amin, Corebima, and Zubaidah (2017) assert that someone who think critically will able to ask question, link relevant information effectively and efficiently, organize information creatively and rationally, and establish consistent conclusions. The implementation of RBL assists the students to actively participate in learning and the students are given an opportunity to learn not only from the material delivered by the teachers, but also being active in the literature discovery, formulating hypotheses, collecting data, analyzing/testing the data, and drawing conclusions (Susiani et al., 2018). Thus, if the RBL-TPS learning model is used in the learning, then the students have passed the information synthesis process to be a flow of thinking so as to form critical arguments independently, share arguments with partners, link various concepts of biodiversity through observation, then communicate paired results to other group friends. These various activities help the students to develop critical thinking skills so that the students can use critical thinking skills in answering the final test. Confirmed by Flores, Matkin, Burbach, Quinn, and Harding (2012) and Kabataş Memiş and Çakan Akkaş (2020) that the ability to think critically can be used by the students to express opinions and correct friends' opinions based on scientific justification. The results of the ANCOVA test on student information literacy after being given a learning with conventional learning models and the RBL-TPS learning model were shown in Table 10 and the results of the LSD advanced test were shown in Table 11, as follows. Table 10. Information literacy hypothesis test results Source Type III sum of squares df Mean square F Sig. Corrected Model 808.148a 2 404.074 15.280 .000 Intercept 9504.734 1 9504.734 359.429 .000 literasi_awal 25.693 1 25.693 .972 .326 model_pembelajaran 689.614 1 689.614 26.078 .000 Error 3279.049 124 26.444 Total 1102530.864 127 Corrected Total 4087.197 126 Table 11. Advanced test results of information literacy Learning model Mean LSD notation Conventional 91.0590 a RBL-TPS 95.5026 a The ANCOVA test results (Table 10) showed that the Fvalue was 26,078 with a significant value of 0.00 <0.05. Based on these results, then H0 was rejected and H1 was accepted. This meant that there is an effect of the learning model on students' information literacy skills. In addition, the results of the LSD advanced test (Table 11) showed that there is no notation difference between the conventional learning model used in the control class and the RBL-TPS learning model used in the experimental class. This proved that the students who were taught using the RBL-TPS and conventional learning models were equally able to develop their information literacy skills, both at SMA 5 Ambon and SMA 9 Ambon. This happens because the students in this digital era JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 251 Narahaubun et al (Empowering students’ critical thinking skills …) have been able to use gadgets to search for information so that between the conventional learning model and the RBL-TPS learning model there is no difference. According to Tuamsuk (2013), information literacy is a skill to respond an information need, the needs of each individual are different tailored to their information needs. Martin (2013) argues that in this digital era, the function of information literacy is to use and disseminate information ethically, but requires the ability to cope with changing information. Moreover, the information literacy is predicted by Internet experience, Internet skills of information seeking, sharing, and verification, attitude towards information verification, and belief in the reliability of information that influenced the role of individuals as media gatekeepers who verify the internet information (Khan & Idris, 2019). According to Kuhlthau (1987), educators need to train information literacy to the students so that they are proficient in interpreting information and using information wisely. This is done by educators so that the students do not take complete information from a source, without giving the name of the source and choosing the correct information to be used. The way that educators can do is to use the right learning model. Melendres (2015) explains that the RBL is a learning model that can develop information literacy skills through responsible information discovery. Therefore, if the RBL learning model is combined with the TPS learning model, the students can search for information then think independently and in pairs; moreover, the students still include sources of information so that they train the students not to become plagiarism from an early age. Singh, Kaur, and Brar (2017) emphasize that the students who understand technology will need the latest information, so the students must be prepared with the skills to identify and retrieve this information. The ANCOVA test results on students' cognitive learning outcomes after being given learning with conventional learning models and the RBL-TPS learning model were shown in Table 12 and the LSD advanced test results were shown in Table 13, as follows. Table 12. Cognitive learning outcomes hypothesis test results Source Type III sum of squares df Mean square F Sig. Corrected Model 5525.828a 2 2762.914 44.818 .000 Intercept 5872.820 1 5872.820 95.265 .000 pre_tes 32.938 1 32.938 .534 .466 model_pembelajaran 3968.839 1 3968.839 64.380 .000 Error 7644.251 124 61.647 Total 638975.000 127 Corrected Total 13170.079 126 Table 13. Advanced test results of cognitive learning outcomes Learning model Mean LSD notation Conventional 63.6719 a RBL-TPS 76.8254 b The ANCOVA test results (Table 12) showed that the Fvalue was 64,380 with a significant value of 0.00 <0.05. Based on these results, H0 was rejected and H1 was accepted. This meant that there is an effect of the learning model on student cognitive learning outcomes. In addition, the LSD advanced test results (Table 13) showed that there is a notation difference between the conventional learning model used in the control class (notation a) and the RBL-TPS learning model used in the experimental class (notation b). This proved that the students who were taught using the RBL-TPS learning model had better mastery of concepts than the students taught using conventional learning models, both at SMA 5 Ambon and SMA 9 Ambon. This indicated that the RBL- TPS learning model was more effective in increasing the students' mastery of concepts compared to the learning model commonly used by the teachers so far (control class). The stages in the RBL-TPS learning model provided a freedom for students to use learning resources independently and these learning resources were not limited to teachers or printed books, but they could use various learning resources such as newspapers, magazines, interview sheets, environment, websites and the internet, videos and pictures. After that, the students synthesized the learning resources independently, the next step was to synthesize reading results in pairs with friends. At this time, there could be an exchange of information between peers. JPBI (Jurnal Pendidikan Biologi Indonesia) Vol. 6, No. 2, July 2020, pp. 243-256 252 Narahaubun et al (Empowering students’ critical thinking skills …) Nugraha (2018) assumes that the RBL learning model emphasizes the activities of students to look for unlimited learning resources via the internet and textbooks so that the teachers are not only a source of learning for students. Furthermore, Boleng (2015) explains that The TPS learning model emphasizes an independence, cooperates with each other, strengthens, completes so that each student during the discussion has the initial capital to argue with each other, fill in, find solutions, and be able to make conclusions on a problem. Therefore, the combination of these two learning models focuses on finding learning resources and processing information independently then sharing information with peers to solve problems. These findings are also similar with the findings provided by Khaeriyah, Warsiti, and Kartika (2015) regarding the combination of resource-based learning models with the scientific approach, the results can improve academic achievement in mastering the material, attitudes and students' critical thinking, while Bahtiar (2013) assumes that TPS learning model combined with RQA can provide better results in increasing mastery of Biology concepts. In addition, seeking information from various sources trains the students to learn independently so that the material being studied can be understood by the students, since the students themselves find this knowledge through searching from various sources of information. Mariyam and Nuraida (2017) postulate that conceptual formation can be done thru incubation stage and memory insertion, these two stages will strengthen or stabilze the students' concepts about the material presented so that maximum learning outcomes are obtained. CONCLUSION Departing from the results of study, it can be concluded that the RBL-TPS learning model improve critical thinking skills, information literacy, and studuents’ cognitive learning outcomes. The score improvement of critical thinking, information literacy, and students’ cognitive are better in the experimental class compared to the control class. In the SMA 9 Ambon, the score of studuents’critical thinking is improved from 58 to, the score of students’ information literacy is improved from 58 to 83, and the score of students’ cognitive learning outcomes is improved from 67 to 95. In the SMA 5 Ambon, the score of studuents’ critical thinking is improved from 61 to 94, the score of students’ information literacy is improved from 50 to 100, and the score of students’ cognitive learning outcomes is improved from 67 to 99. Additionally, the results of ANCOVA test found that there is an influence on the RBL-TPS learning model to the students’ critical thinking skills, information literacy, and cognitive learning outcomes at SMA 9 Ambon and SMA 5 Ambon (0.00<0.05). The information obtained from the results of this study is a new learning syntax, namely a syntax of RBL-TPS model so that the biology teachers can implement the RBL-TPS model in other biological concepts. 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