Modeling strategies enhanced by metacognitive tools in high school physics to support student conceptual trajectories and understanding of electricity
Modeling is considered an important scientific practice, and modeling instruction has the potential to support conceptual change in students in physics. However, when students are not taught how to think about modeling, and how to develop and use models, the learning potential of modeling may be lim...
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| Veröffentlicht in: | Science education (Salem, Mass.) Mass.), 2018-07, Vol.102 (4), p.711-743 |
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| creator | Wade‐Jaimes, Katherine Demir, Kadir Qureshi, Azhar |
| description | Modeling is considered an important scientific practice, and modeling instruction has the potential to support conceptual change in students in physics. However, when students are not taught how to think about modeling, and how to develop and use models, the learning potential of modeling may be limited. This paper argues that the use and explicit teaching of metacognitive tools like interactive questioning and individual reflection increase students’ ability to use and make sense of models. We present a sequence of activities incorporating metacognitive tools with a variety of models (mental, physical, simulated, and mathematical) in a high school physics unit of electricity. Using data from classroom observations, individual student reflections, group‐created posters, and classroom discussion, we found evidence to demonstrate the complicated nature of conceptual change, the importance of using a variety of different representations (models) of a phenomenon, and the critical role of the teacher in learning. Teachers need to be aware of this process and able to give students the time they need to fully explore and develop multiple models and support to think critically about models. Although many classrooms are limited in time, this process is necessary to move beyond rote memorization toward meaningful conceptual change. |
| doi_str_mv | 10.1002/sce.21444 |
| format | Article |
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| source | Education Source; Wiley Online Library Journals Frontfile Complete |
| subjects | Classroom Communication Classroom Observation Techniques Concept Teaching conceptual change Direct Instruction Discussion (Teaching Technique) Educational Strategies Electricity Energy Education High School Students Instructional Effectiveness Learning Memorization Metacognition modeling Modeling (Psychology) Observation Physics Reflection Science education Scientific Concepts Secondary School Science Students Teacher Role Teaching Methods |
| title | Modeling strategies enhanced by metacognitive tools in high school physics to support student conceptual trajectories and understanding of electricity |
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