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Integrating Computational Thinking into Elementary Science Curriculum: an Examination of Activities that Support Students’ Computational Thinking in the Service of Disciplinary Learning
Using an example of a grade 3 science unit about population changes during competition for resources, we describe how we integrated computational thinking (CT) into existing curriculum identifying three levels of depth of integration: identifying connections that already exist, enhancing and strengt...
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| Published in: | Journal of science education and technology 2020-02, Vol.29 (1), p.53-64 |
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| container_title | Journal of science education and technology |
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| creator | Waterman, Kevin P Goldsmith, Lynn Pasquale, Marian |
| description | Using an example of a grade 3 science unit about population changes during competition for resources, we describe how we integrated computational thinking (CT) into existing curriculum identifying three levels of depth of integration: identifying connections that already exist, enhancing and strengthening connections, and extending units to include activities that more explicitly develop students’ CT. We discuss students’ understanding of the relationship between a simple model of an ecosystem and the actual phenomenon it represents, their engagement with the unit’s data-gathering and data analysis activities, their ability to engage in sense-making regarding data they generated and analyzed, and how collectively the study supports their understanding of the complex system. This example module is part of “Broadening Participation of Elementary School Teachers and Students in Computer Science through STEM Integration and Statewide Collaboration,” a National Science Foundation-funded collaboration among Massachusetts teacher educators, researchers, teachers, and state-level education administrators that developed and implemented a number of elementary grade, CT-integrated science and mathematics curriculum modules. Collectively, these modules are designed to develop practices related to several key CT topics: abstraction, data, modeling and simulation, and algorithms. These CT topics support the development of core skills related to, but not exclusively the domain of, computer science. The strategy of integrating CT into core elementary STEM subject areas was intended to cultivate CT practices in support of science learning. |
| doi_str_mv | 10.1007/s10956-019-09801-y |
| format | article |
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We discuss students’ understanding of the relationship between a simple model of an ecosystem and the actual phenomenon it represents, their engagement with the unit’s data-gathering and data analysis activities, their ability to engage in sense-making regarding data they generated and analyzed, and how collectively the study supports their understanding of the complex system. This example module is part of “Broadening Participation of Elementary School Teachers and Students in Computer Science through STEM Integration and Statewide Collaboration,” a National Science Foundation-funded collaboration among Massachusetts teacher educators, researchers, teachers, and state-level education administrators that developed and implemented a number of elementary grade, CT-integrated science and mathematics curriculum modules. Collectively, these modules are designed to develop practices related to several key CT topics: abstraction, data, modeling and simulation, and algorithms. 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| subjects | Algorithms Collaboration Complex systems Computation Computer applications Computer science Computer simulation Curricula Curriculum Development Data Analysis Education Educational Technology Elementary School Curriculum Elementary School Science Elementary School Teachers Grade 3 Information management Integration Learning Learning Activities Modules Population changes Population Trends Science Curriculum Science Education Science Teachers Sciences education STEM Education Students Teacher Educators Teachers Thinking Skills |
| title | Integrating Computational Thinking into Elementary Science Curriculum: an Examination of Activities that Support Students’ Computational Thinking in the Service of Disciplinary Learning |
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