设计一个教师将计算思维融入基础科学的框架

IF 3.6 1区 教育学 Q1 EDUCATION & EDUCATIONAL RESEARCH
Lautaro Cabrera, Diane Jass Ketelhut, Kelly Mills, Heather Killen, Merijke Coenraad, Virginia L. Byrne, Jandelyn Dawn Plane
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引用次数: 0

摘要

随着专业科学的计算性越来越强,研究人员和教育工作者正在倡导将计算思维(CT)融入科学教育。研究人员和政策制定者认为,计算思维学习机会应从小学开始,贯穿 K-12 年级。虽然研究人员和政策制定者已经明确了学生应如何参与计算思维的科学学习,但计算思维整合的成功与否最终取决于小学教师如何在科学课中实施计算思维。对能够整合 CT 的教师的这一新需求催生了对有效概念工具的需求,教师教育者和专业发展设计者可以利用这些工具来培养小学教师对课堂 CT 的理解和操作能力。然而,现有的 CT 整合框架有其局限性。现有的框架要么忽略了小学年级,要么将 CT 孤立地概念化,没有与科学相结合,要么没有在师范教育背景下进行过测试。在回顾了现有的 CT 整合框架并详细介绍了科学教师教育文献中的一个重要空白之后,我们提出了将 CT 整合到小学科学教育中的框架,并特别关注如何与教师一起使用这一框架。在我们以设计为基础的研究中,我们(a)解释了设计该框架的决策过程;(b)描述了当我们在一批职前和在职教师中实施该框架时,它所提供的教学能力和挑战;(c)提供了在教师教育背景下使用该框架的建议;以及(d)从理论上提出了继续完善该框架的可能途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Designing a framework for teachers' integration of computational thinking into elementary science

Designing a framework for teachers' integration of computational thinking into elementary science

As professional science becomes increasingly computational, researchers and educators are advocating for the integration of computational thinking (CT) into science education. Researchers and policymakers have argued that CT learning opportunities should begin in elementary school and span across the K-12 grades. While researchers and policymakers have specified how students should engage in CT for science learning, the success of CT integration ultimately depends on how elementary teachers implement CT in their science lessons. This new demand for teachers who can integrate CT has created a need for effective conceptual tools that teacher educators and professional development designers can use to develop elementary teachers' understanding and operationalization of CT for their classrooms. However, existing frameworks for CT integration have limitations. Existing frameworks either overlook the elementary grades, conceptualize CT in isolation and not integrated into science, and/or have not been tested in teacher education contexts. After reviewing existing CT integration frameworks and detailing an important gap in the science teacher education literature, we present our framework for the integration of CT into elementary science education, with a special focus on how to use this framework with teachers. Situated within our design-based research study, we (a) explain the decision-making process of designing the framework; (b) describe the pedagogical affordances and challenges it provided as we implemented it with a cohort of pre- and in-service teachers; (c) provide suggestions for its use in teacher education contexts; and (d) theorize possible pathways to continue its refinement.

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来源期刊
Journal of Research in Science Teaching
Journal of Research in Science Teaching EDUCATION & EDUCATIONAL RESEARCH-
CiteScore
8.80
自引率
19.60%
发文量
96
期刊介绍: Journal of Research in Science Teaching, the official journal of NARST: A Worldwide Organization for Improving Science Teaching and Learning Through Research, publishes reports for science education researchers and practitioners on issues of science teaching and learning and science education policy. Scholarly manuscripts within the domain of the Journal of Research in Science Teaching include, but are not limited to, investigations employing qualitative, ethnographic, historical, survey, philosophical, case study research, quantitative, experimental, quasi-experimental, data mining, and data analytics approaches; position papers; policy perspectives; critical reviews of the literature; and comments and criticism.
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