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Habiddin
Universitas Negeri Malang
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Multimedia vs concrete model: Review of studies employing the tools in chemistry teaching Rooserina Kusumaningdyah; Habiddin Habiddin; Yudhi Utomo
J-PEK (Jurnal Pembelajaran Kimia) Vol 6, No 2 (2021): J-PEK (JURNAL PEMBELAJARAN KIMIA)
Publisher : Universitas Negeri Malang

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.17977/um026v6i22021p072

Abstract

This paper describes previous studies regarding the use of multimedia or virtual model and concrete model to improve students’ understanding of chemistry. Thirty-three relevant papers in various topics, including stereochemistry, symmetry, chemical bonding,  law conservation of matter, and others, were found and discussed. In particular, relevant studies in stereochemistry teaching is also discussed. REFERENCESAnggriawan, B. (2017). Pengaruh Pembelajaran Penemuan Terbimbing Berbantuan Multimedia terhadap Pemahaman Materi Simetri Mahasiswa dengan Kemampuan Spasial yang Berbeda. Universitas Negeri Malang.Beauchamp, P. S. (1984). “Absolutely” Simple Stereochemistry. Journal of Chemical Education, 61(8), 666. https://doi.org/10.1021/ed061p666Boukhechem, M.-S., Dumon, A., & Zouikri, M. (2011). The Acquisition of Stereochemical Knowledge by Algerian Students Intending to Teach Physical Sciences. Chemical Education Research and  Practise, 12(3), 331–343. https://doi.org/10.1039/C1RP90040DChen, D., Chen, X., & Gao, W. (2013). The Application and Perspective of Multimedia Technology in Chemistry Experimental Instruction in China. Creative Education, 04(04), 241–247. https://doi.org/10.4236/ce.2013.44035Chen, D.-W., & Catrambone, R. (2014). Effects of Multimedia Interactivity on Spatial Task Learning Outcomes. Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 58(1), 1356–1360. https://doi.org/10.1177/1541931214581283da Silva Júnior, J. N., Sousa Lima, M. A., Xerez Moreira, J. V., Oliveira Alexandre, F. S., de Almeida, D. M., de Oliveira, M. da C. F., & Melo Leite Junior, A. J. (2017). Stereogame: An Interactive Computer Game That Engages Students in Reviewing Stereochemistry Concepts. Journal of Chemical Education, 94(2), 248–250. https://doi.org/10.1021/acs.jchemed.6b00475Dayame, A. M. (2019). The Effects of Manipulative and Visual Models in Conceptualizing Fractions. International Journal of Advanced Research and Publications, 3(8), 80–85.Dori, Y. J., & Barak, M. (2001). Virtual and Physical Molecular Modeling: Fostering Model Perception and Spatial Understanding. Educational Technology & Society, 4(1), 61–74.Hakim, M. F., Maksum, A. H., Saragih, Y., & Hasanah, C. S. (2020). Analysis on the implementation of virtual versus reality laboratory. J-PEK (Jurnal Pembelajaran Kimia), 5(2), 59–65. https://doi.org/10.17977/UM026V5I22020P059Harrold, M. W. (1995). Computer-Based Exercises to Supplement the Teaching of Stereochemical Aspects of Drug Action1,2. American Journal of Pharmaceutical Education, 59, 20–26.Kirk, J. (2015). Using Manipulatives in The Chemisty Classroom as a Tool to Increase The Understanding and Knowledge of The Law of Conversation of Matter. St. John Fisher College: Fisher Digital Publications:Knowles, T. H. (2017). Using Eye-Tracking and Molecular Modelling to Explore Students’ Strategies for Solving Organic Stereochemical Problems. University of Northern Colorado.Koutalas, V. G., Antonoglou, L. D., Charistos, N. D., & Sigalas, M. P. (2014). Investigation of Students’ Ability to Transform and Translate 2D Molecular Diagrammatic Representations and its Relationship to Spatial Ability and Prior Chemistry Knowledge. Procedia - Social and Behavioral Sciences, 152, 698–703. https://doi.org/10.1016/j.sbspro.2014.09.265Lou, S.-J., & Lin, H.-C. (2012). Improving the Effectiveness of Organic Chemistry Experiments through Multimedia Teaching Materials for Junior High School Students. The Turkish Online Journal of Educational Technology, 11(2), 135–141.Muchson, M., Munzil, M., Winarni, B. E., & Agusningtyas, D. (2019). Pengembangan virtual lab berbasis android pada materi asam basa untuk siswa SMA. J-PEK (Jurnal Pembelajaran Kimia), 4(1), 51–65. https://doi.org/10.17977/UM026V4I12019P051O’Brien, M. (2016). Creating 3-Dimensional Molecular Models to Help Students Visualize Stereoselective Reaction Pathways. Journal of Chemical Education, 93(9), 1663–1666. https://doi.org/10.1021/acs.jchemed.6b00250Olimpo, J. T., Kumi, B. C., Wroblewski, R., & Dixon, B. L. (2015). Examining The Relationship Between 2D Diagrammatic Conventions and Students’ Success on Representational Translation Tasks in Organic Chemistry. Chemistry Education Research and Practice, 16(1), 143–153. https://doi.org/10.1039/C4RP00169AOlkun, S. (2003). Comparing Computer versus Concrete Manipulatives in Learning 2D Geometry. Journal of Computers in Mathematics and Science Teaching, 22(1), 43–56. https://doi.org/10.1501/0000984Sentongo, J., Kyakulaga, R., & Kibirige, I. (2013). The Effect of Using Computer Simulations in Teaching Chemical Bonding: Experiences with Ugandan Learners. International Journal of Education Science, 5(4), 433–441.Sevi̇Nç, B. (2010). The Effect Of Computer Based Instruction Enhanced With Concept Maps On Students’ Understanding Of Stereochemistry. International Conference on New Trends in Education and Their Implications, 301–306.Stieff, M., Bateman, R. C., & Uttal, D. H. (2005). Teaching and Learning with Three-dimensional Representations. In J. K. Gilbert (Ed.), Visualization in Science Education (pp. 93–120). Springer Netherlands. https://doi.org/10.1007/1-4020-3613-2_7Stieff, M., Scopelitis, S., Lira, M. E., & Desutter, D. (2016). Improving Representational Competence with Concrete Models. Science Education, 100(2), 344–363. https://doi.org/10.1002/sce.21203Stull, A. T., Barrett, T., & Hegarty, M. (2013). Usability of Concrete and Virtual Models in Chemistry Instruction. Computers in Human Behavior, 29(6), 2546–2556. https://doi.org/10.1016/j.chb.2013.06.012Stull, A. T., Hegarty, M., Dixon, B., & Stieff, M. (2012). Representational Translation With Concrete Models in Organic Chemistry. Cognition and Instruction, 30(4), 404–434. https://doi.org/10.1080/07370008.2012.719956Thayban, T., Habiddin, H., & Utomo, Y. (2020). Concrete Model VS Virtual Model: Roles and Implications in Chemistry Learning. J-PEK (Jurnal Pembelajaran Kimia), 5(2), 90–107. https://doi.org/10.17977/UM026V5I22020P090Thayban, T., Habiddin, H., Utomo, Y., & Muarifin, M. (2021). Understanding of Symmetry: Measuring the Contribution of Virtual and Concrete Models for Students with Different Spatial Abilities. Acta Chimica Slovenica, 68(3). https://doi.org/10.17344/acsi.2021.6836
PENGARUH PENDEKATAN INKUIRI TERBIMBING TERHADAP HASIL BELAJAR DAN SIKAP ILMIAH SISWA KELAS XI IPA SMA NEGERI 1 LAWANG PADA MATERI LARUTAN PENYANGGA DAN HIDROLISIS GARAM Arifah Zurotunisa; Habiddin Habiddin; Ida Bagus Suryadharma
J-PEK (Jurnal Pembelajaran Kimia) Vol 1, No 2 (2016): Jurnal Pembelajaran Kimia (J-PEK) Vol. 1 No. 2 2016
Publisher : Universitas Negeri Malang

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (329.304 KB)

Abstract

Abstrak Tujuan penelitian ini adalah untuk mengetahui perbedaan hasil belajar antara siswa yang dibelajarkan dengan pendekatan inkuiri terbimbing dan siswa yang dibelajarkan dengan Pendekatan konvensional (verifikasi) pada materi larutan penyangga dan hidrolisis garam. Selain itu juga ingin diketahui sikap ilmiah siswa kelas XI IPA SMAN 1 Lawang yang dibelajarkan dengan pendekatan inkuiri terbimbing dan siswa yang dibelajarkan secara konvensional pada materi pokok larutan penyangga dan hidrolisis garam. Rancangan penelitian yang digunakan adalah eksperimental semu. Kegiatan analisis data meliputi uji-t dengan signifikansi 0,05 untuk hasi belajar kognitif. Data sikap ilmiah diperoleh melalui angket yang dianalisis secara deskriptif. Hasil penelitian menunjukkan terdapat perbedaan hasil belajar kognitif  siswa yang dibelajarkan menggunakan pendekatan pembelajaran inkuiri terbimbing dengan siswa yang dibelajarkan menggunakan pendekatan konvensional (verifikasi) pada materi larutan penyangga dan hidrolisis garam. Sikap ilmiah siswa yang dibelajarkan menggunakan metode pembelajaran inkuiri terbimbing lebih tinggi daripada siswa yang dibelajarkan menggunakan konvensional (verifikasi). Kata Kunci : Inkuiri terbimbing, Hasil belajar, Sikap Ilmiah, Larutan Penyangga, Hidrolisis garam Abstract This research was conducted to determine the difference  of learning achievements between students who learned with guided inquiry method and students who learned with the conventional method (verification) in the buffer and salt hydrolysis topic. Another objective is to determine the difference scientific attitude of student at both clases. Data were collected at XI class of science program SMA Negeri 1 Lawang. A quasi-experimental design post-test-only and descriptive design were used for this research. Data analysis was started by by for scientific attitude t-test with a significance of 0.05. Questionnaire data was analysis by quantitative descriptive analysis. The reseaarch showed that (1) there are differences in cognitive learning achievements of students that learned using guided inquiry methods and students that learned using conventional (verification) method in the buffer and salt hydrolysis topic. (2) the scientific attitude of students that learned using guided inquiry learning method is higher than the students that learned using conventional (verification). Keywords: Guided Inquiry, learning achievement, Scientific Attitude, Buffer Solution, salt hydrolysis
HOTS & Problem-Based Learning (PBL) with blended learning Laili Mei Sulistiyani; Habiddin Habiddin; Yahmin Yahmin
J-PEK (Jurnal Pembelajaran Kimia) Vol 7, No 1 (2022): J-PEK (JURNAL PEMBELAJARAN KIMIA)
Publisher : Universitas Negeri Malang

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.17977/um026v7i12022p001

Abstract

In the world of education, attainment of competence does not only involve increasing knowledge but must be equipped with creative abilities, high-level thinking, strong character, and supported by the ability to utilize information and communication. One way to achieve these competencies is by using blended learning-based problem-based learning methods. This study seeks to review articles on improving students' higher-order thinking skills using blended learning based on problem-based learning methods to investigate the combination of these two methods in increasing students' HOTS.
Concrete Model VS Virtual Model: Roles and Implications in Chemistry Learning Thayban Thayban; Habiddin Habiddin; Yudhi Utomo
J-PEK (Jurnal Pembelajaran Kimia) Vol 5, No 2 (2020): J-PEK (JURNAL PEMBELAJARAN KIMIA)
Publisher : Universitas Negeri Malang

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.17977/um026v5i22020p090

Abstract

Mastering the topic of symmetry requires a good representational competence to smoothly understand, visualize, and manipulate the movement of three-dimensional objects. This literature study aimed to describe how concrete and virtual media can be utilized in improving students’ understanding of the topic. The study implies that the thinking process, cognitive tasks, interactions, mental models, and the completeness features displayed by the two models in identifying all symmetrical operations are the distinguishing factors of the effectiveness of the two formats in affecting students’ understanding. The study also implies that the virtual format will contribute to students’ understanding better than the concrete format does. However, the empirical study must be explored further to ensure the difference between the two formats.
Interactive Instructional: Theoretical Perspective and Its Potential Support in Stimulating Students’ Higher Order Thinking Skills (HOTS) Rafika Fauzia Ulfa; Habiddin Habiddin; Yudhi Utomo
J-PEK (Jurnal Pembelajaran Kimia) Vol 6, No 1 (2021): J-PEK (JURNAL PEMBELAJARAN KIMIA)
Publisher : Universitas Negeri Malang

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.17977/um026v6i12021p001

Abstract

In this disruptive era, the success of teaching approaches that encourage students’ creativity and innovation is presented in students’ attained high-order thinking skills (HOTS). Consequently, the attainment of HOTS aids someone to avert negative things since they are capable of analyzing and evaluating their obtained information. Besides, HOTS also facilitates the process of students attaining knowledge, generating questions, properly interpreting information, and drawing a conclusion for an issue, with solid reasons, an open mind, and an effective means to communicate it. This article presents a theoretical study on the interactive instructional learning model and identifies its potential in accelerating students’ HOTS. It aims to introduce the interactive instructional model in chemistry learning. Further, this model can be adopted in a study with a more intensive evaluation of its empirical contribution to chemistry learning. The learning syntax for this model has been formulated for the Basic Chemistry Class 1.ReferencesBrookhart, S. M. (2010). How To Assess Higher Order thinking Skills in your classroom. Alexandria.Fearon, D. D., Copeland, D., & Saxon, T. F. (2013). The Relationship Between Parenting Styles and Creativity in a Sample of Jamaican Children. Creativity Research Journal, 25(1), 119–128. https://doi.org/10.1080/10400419.2013.752287Ghani, I. . B. ., Ibrahim, N. ., Yahaya, N. ., & Surif, J. (2017). Enhancing students’ HOTS in laboratory educational activity by using concept map as an alternative assessment tool. Chemistry Education Research and Practice, 18(4), 849–874. https://doi.org/10.1039/C7RP00120GHabiddin, H., & Page, E. M. (2020). Probing Students’ Higher Order Thinking Skills Using Pictorial Style Questions. Macedonian Journal of Chemistry and Chemical Engineering, 39(2), 251–263. https://doi.org/10.20450/mjcce.2020.2133Habiddin, H., & Page, E. M. (2021). Examining Students’ Ability to Solve Algorithmic and Pictorial Style Questions in Chemical Kinetics. International Journal of Science and Mathematics Education, 19(1), 65–85. https://doi.org/10.1007/s10763-019-10037-wHabiddin, H., & Page, E. M. (2018). Measuring Indonesian chemistry students’ Higher Order Thinking Skills (HOTS) in solving chemical kinetics questions. In Y. Rahmawati & P. C. Taylor (Eds.), Empowering Science and Mathematics for Global Competitiveness; Proceedings of the Science and Mathematics International Conference (SMIC 2018) (pp. 215–222). CRC Press Taylor & Francis.Heong, Y. M., Sern, L., Kiong, T. T., & Mohamad, M. (2016). The Role of Higher Order Thinking Skills in Green Skill Development.Herunata, H., Widarti, H. R., Amalia, R., Sulistina, O., Habiddin, H., & Rosli, M. S. bin. (2020). An analysis of higher order thinking skill (HOTs) in chemistry national examination for senior high school. AIP Conference Proceedings, 2215(1), 20009. https://doi.org/10.1063/5.0000639Horan, R. (2007). The Relationship Between Creativity and Intelligence: A Combined Yogic-Scientific Approach. Creativity Research Journal, 19(2–3), 179–202. https://doi.org/10.1080/10400410701397230Lather, A. S., Jain, S., & Shukla, A. D. (2014). Student’s Creativity in Relation to Locus of Control: a Study of Mysore University, India. The International Journal of Indian Psychȯlogy , 2(1), 146–165. http://ijip.in/article-details/?dip=18-01-058-20140201Lewis, A., & Smith, D. (1993). Defining Higher Order Thinking. Theory Into Practice, 32(3), 131–137.Lim, S., & Smith, J. (2008). The Structural Relationships of Parenting Style, Creative Personality, and Loneliness. Creativity Research Journal, 20(4), 412–419. https://doi.org/10.1080/10400410802391868McLoughlin, D., & Mynard, J. (2009). An analysis of higher order thinking in online discussions. Innovations in Education and Teaching International, 46(2), 147–160.Narciss, S. (2007). Feedback Strategies for Interactive Learning Tasks. In Handbook of Research on Educational Communications and Technology. Routledge. https://doi.org/10.4324/9780203880869.ch11Paideya, V., & Sookrajh, R. (2010). Exploring the use of supplemental instruction: Supporting deep understanding and higher-order thinking in Chemistry. South African Journal of Higher Education, 24(5), 758–770.Pannells, T. C., & Claxton, A. F. (2008). Happiness, creative ideation, and locus of control. Creativity Research Journal, 20(1), 67–71. https://doi.org/10.1080/10400410701842029Phakiti, A. (2018). Assessing Higher-Order Thinking Skills in Language Learning. In The TESOL Encyclopedia of English Language Teaching (pp. 1–7). https://doi.org/doi:10.1002/9781118784235.eelt0380Proske, A., Körndle, H., & Narciss, S. (2012). Interactive Learning Tasks BT  - Encyclopedia of the Sciences of Learning (N. M. Seel (ed.); pp. 1606–1610). Springer US. https://doi.org/10.1007/978-1-4419-1428-6_1100Resnick, L. B. (1987). Education and Learning to Think. National Academy Press.Toledo, S., & Dubas, J. M. (2016). Encouraging Higher-Order Thinking in General Chemistry by Scaffolding Student Learning Using Marzano’s Taxonomy. Journal of Chemical Education, 93(1), 64–69. https://doi.org/10.1021/acs.jchemed.5b00184Zohar, A. (2004). Elements of Teachers’ Pedagogical Knowledge Regarding Instruction of Higher Order Thinking. Journal of Science Teacher Education, 15(4), 293–312. https://doi.org/10.1023/B:JSTE.0000048332.39591.e3Zohar, A., & Dori, Y. J. (2003). Higher Order Thinking Skills and Low-Achieving Students: Are They Mutually Exclusive? Journal of the Learning Sciences, 12(3), 145–181. https://doi.org/10.1207/S15327809JLS1202_1Zoller, U, & Dori, Y. J. (2002). Algorithmic, LOCS and HOCS (chemistry) exam questions: performance and attitudes of college students. International Journal of Science Education, 24(2), 185–203. https://doi.org/10.1080/09500690110049060Zoller, Uri, & Pushkin, D. (2007). Matching Higher-Order Cognitive Skills (HOCS) promotion goals with problem-based laboratory practice in a freshman organic chemistry course. Chemistry Education Research and Practice, 8(2), 153–171
THE IMPLEMENTATION OF RECIPROCAL TEACHING MODEL TO IMPROVE STUDENTS’ ACHIEVEMENT ON ACID-BASE CONCEPTS Maysara Maysara; Habiddin Habiddin
J-PEK (Jurnal Pembelajaran Kimia) Vol 4, No 1 (2019): J-PEK (JURNAL PEMBELAJARAN KIMIA)
Publisher : Universitas Negeri Malang

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (326.869 KB) | DOI: 10.17977/um026v4i12019p014

Abstract

This study aimed to describe the improvement of students’ learning outcomes using reciprocal teaching model. The improvement is measured based on the results of pre-test and posttest. 24 students of XI class at SMA Negeri 4 Wangi-Wangi taking sciences major participated in this study. This one group pre-test & post-test research design used an instrument (test) in the form of multiple-choice questions. The questions were constructed by considering the cognitive level in Bloom taxonomy. The study reveals that students’ improvement falls in the moderate category with the N-gain score of 0.69. The study also uncovered that students’ ability in answering questions decreases with the increase in the cognitive level of the questions
Training of Development of Inquiry-Based and Project-Based Chemistry Learning Design for Chemistry & Science Teachers Oktavia Sulistina; Hayuni Retno Widarti; Habiddin Habiddin; Herunata Herunata; Yahmin Yahmin; Samudra Mutiara Hasanah; Dhea Fairuza Zahirah
J-PEK (Jurnal Pembelajaran Kimia) Vol 8, No 1 (2023): J-PEK (JURNAL PEMBELAJARAN KIMIA)
Publisher : Universitas Negeri Malang

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Abstract

Abstrak – Nowadays, the demands of curriculum are increasing in achieving better standards of learning process. The low ability of chemistry and science teachers in developing inquiry-based and project-based learning designs is a problem that must be solved. The ability of teachers in making learning designs is one of the pedagogic competencies and professional competencies that teachers must master in their professional development. So there is a need for community service or training to teachers to facilitate this. The method of implementing this community service activity includes the presentation of material on inquiry-based and project-based chemistry learning design, discussion and question and answer, and assistance to teachers in developing the learning design, until teachers are able to make inquiry-based and project-based chemistry learning tools (including lesson plans, teaching materials, and assessment instruments). The result of the training activities was an increase in the knowledge and skills of chemistry and science teachers regarding making inquiry-based and project-based learning designs. Enthusiasm and curiosity in developing knowledge about learning design make this training activity useful for participants.Keywords: Learning Design; Inquiry; Project; Teacher; Training
Co-Authors Aceng Haetami Afis Baghiz Safruddin Afis Baghiz Syafruddin Afrahamiryano Afrahamiryano Ahmad Naqib bin Shuid Amat Mukhadis Ameliana, Devita Novi Ananta Ardyansyah Andika Bagus Nur Rahma Putra, Andika Bagus Nur Rahma Arif Putra Arifah Zurotunisa Aris Ichwanto, Muhammad Asnan Wahyudi Asnan Wahyudi Asnan Wahyudi Bambang Wahyudi Bambang Wahyudi Bambang Wahyudi Bernada Uni Tatya Akmal Burhanuddin Ronggopuro Citra Ayu Dewi Dede Yayah Rokayah Deni Ainur Rokhim Devita Novi Ameliana Dhea Fairuza Zahirah Dinny Ariana Elizabeth Mary Page Eva Kurnia Fanny Iga Widiastuti Faridah Amala Firda Amalia Frida Kristining Tyas Hafif Ahmad Abdul Aziz Hayuni Retno Widarti Herunata Herunata I Wayan Dasna Ida Bagus Suryadharma Irene Lusita Nagol Isnatul Husniah Jacky Anggara Nenohai Juwita Karina Pratiwi Kafita Krisnatul Islamiyah Krisma Dewi Firdaus Indasari Laili Mei Sulistiyani Lestari, Linda Ayu Lilla Farizka Linda Ayu Lestari Made Duananda Kartika Degeng Maysara Maysara Miftahul Jannah Moch Chesa Nur Hidayat Arif Putra Mohammad Musthofa Al Ansyorie Muhammad Fajar Marsuki Muhammad Muchson Muhammad Roy Asrori Muhammad Suaidy Muhammad Sua’idy Munzil Nassa Amrilizia Nur Candra Eka Setiawan Nur Hamid Nur Indah Agustina Nur Indah Agustina Nurul Ulfatin Nuryono Nuryono Oktavia Sulistina Parlan Parlan Parlan Parlan Purba, Leony Sanga Lamsari Qodriyah, Nur Romadhona Lailatul Rafika Fauzia Ulfa Richa Nan Maharani Ristiwi Peni Ristiwi Peni Ristiwi Peni Rolisonia Rona Kecima Jeharut Rooserina Kusumaningdyah Rucira Pavita Saefuddin Saefuddin Samudra Mutiara Hasanah Setiawan, Nur Candra Eka Shorihatul Inayah Sri Rahayu Sri Rahayu Su?aidy, Muhammad Su’aidy, Muhammad Subandi Subandi Subandi Subandi Surjani Wonorahardjo Syaiful Arif Syamyafiya Afiyanti Thayban Thayban Tuwoso Tuwoso Tze Kiong Tee Utomo, Yudhi Vita Ayu Kusuma Dewi Yahmin Yahmin Zelen Surya Minata