Context-based learning (CBL), promoting students' scientific text comprehension, and fostering metacognitive skills, plays an important role in science education. Our study involves CBL through comprehension and analysis of adapted scientific articles. We developed a module which integrates metacognitive prompts for guiding students to monitor their understanding and improve their scientific text comprehension. We investigated the effect of these metacognitive prompts on scientific text comprehension as part of CBL in chemistry. About 670 high school chemistry students were randomly divided into three groups exposed to high-and low-intensity CBL. One of the high-intensity groups was also exposed to metacognitive prompts. Research tools included pre-and post-questionnaires aimed at measuring students' conceptual chemistry understanding and metacognitive knowledge in the context of reading strategies, before and after exposure to the CBL. Chemistry understanding was reflected by students' ability to identify the main subject of the adapted article and by explaining concepts both textually and visually. We found that high-intensity CBL combined with metacognitive prompts improved students' chemistry understanding of the adapted scientific articles and the ability to regulate their learning. Our study establishes that reading context-based adapted scientific articles advances students' conceptual chemistry understanding. These gains are strongly amplified by domain-specific metacognitive prompts. ARTICLE HISTORY
In many countries, the choice of a STEM career, especially in chemistry, is decreasing. A shortage of appropriately skilled workers can become a threat to any country's future achievements. Our research strives to understand behavioral trends and career choice factors related to personal and environmental themes. Building on the foundations of the Social Cognitive Career Theory, the research sheds light on prospective trends and retrospective perceptions of chemistry-related professionals in choosing chemistry in high school, as a career, and as a STEM occupation. To analyze the prospective trends in choosing chemistry, we used data curated by the Israel Central Bureau of Statistics on 545 778 high school graduates. For the retrospective perceptions of choosing a chemistry career, we investigated three research groups (N = 190): chemists and chemical engineers, chemistry teachers, and third year undergraduate chemistry students. We found that choosing chemistry as a major and profession decreases from high school to higher education. Women tend to choose chemistry more than men at high school and university levels, and minorities tend to choose it more in high school but less in higher education compared to non-minorities. Task-oriented self-efficacy was the factor which contributed the most to chemistry career choice in all three research groups. The theoretical contribution is the unique SCCT application through the integration of both the prospective views on the behavioral theme and the retrospective views on the personal and environmental themes. Furthermore, we present new chemistry-related factors within the personal theme of this theoretical framework that can extend the SCCT framework.
For an educational reform to succeed, teachers need to adjust their perceptions to the reform's new curricula and strategies and cope with new content, as well as new teaching and assessment strategies. Developing students' scientific literacy through context-based chemistry and higher order thinking skills was the framework for establishing a new chemistry curriculum for Israeli high school students. As part of this endeavor, we developed the Taste of Chemistry module, which focuses on contextbased chemistry, chemical understanding, and higher order thinking skills. Our research objectives were (a) to identify the challenges and difficulties chemistry teachers faced, as well as the advantages they found, while teaching and assessing the Taste of Chemistry module; and (b) to investigate how they coped with teaching and assessing thinking skills that include analyzing data from graphs and tables, transferring between multiple representations and, transferring between chemistry understanding levels.
Most undergraduate chemistry courses and a few high school honors courses, which focus on physical chemistry and quantum mechanics, are highly mathematically-oriented. At the Technion, Israel Institute of Technology, we developed a new module for high school students, titledChemistry – From “the Hole” to “the Whole”: From the Nanoscale to Microelectronics. The module is based on a qualitative approach to teaching quantum chemistry, emphasizing interdisciplinary real-life applications and integration of visualization. While aimed at honors high school chemistry students, the module was also partially implemented and assessed in an undergraduate chemistry course. The research objective was to investigate the effect of the module on the visual and textual understanding of quantum mechanical concepts among 122 honors and 65 volunteer undergraduate chemistry students. The research tools included students' pre- and post-questionnaires. High school honors and undergraduate students, who were exposed to the module, significantly improved their textual and visual understanding of quantum mechanical concepts and their ability to move across illustrations and explanations. Honors and undergraduate students minimized the gap that had existed between them in terms of integrating micro and quantum levels into their post-questionnaire answers. Our findings augment the current set of the four chemistry understanding levels – macro, micro, symbol and process – by adding the quantum mechanical level as a fifth level of chemistry understanding. The study contributes to teaching physical chemistry by providing a tool for learning, assessment, and research of chemistry understandingviaboth visual and textual modes.
In the contemporary landscape of science education, teachers aspire to implement approaches that engage students with diverse teaching methods in diverse learning environments. By reviewing educational literature that deals with chemical escape rooms (ChEsRms), we can find several purposes they serve; however, only a few papers used ChEsRms for assessing student’s knowledge and 21st century skills. The “Escape Room-based Educational Assessment” (EREA) has been built, at the Faculty of Education in our institution, to serve high-school chemistry teachers and their students as an alternative learning and assessment environment. A variety of puzzles are described in this activity paper. The escape room is equipped with cameras that record students’ work while solving the puzzles, and at the same time, they can be observed by their teachers from a control room. Teachers were asked to provide feedback on the activity and specify which puzzles required the implementation of significant chemical knowledge, high order thinking skills (analysis, synthesis, or evaluation), and thinking creatively, for their solution. Based on the teachers’ perception, the skills required while solving the puzzles were mapped. Teachers addressed a variety of aspects: (a) domain specific skills in chemistry such as the implementation and synthesis of chemical knowledge, (b) scientific practices such as question posing and problem solving, and (c) 21st century skills such as collaboration, taking initiative, and creativity.
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