Teachers’ Incorporation of Argumentation to Support Engineering Learning in STEM Integration Curricula

Q1 Social Sciences

Journal of Pre-College Engineering Education Research Pub Date : 2017-06-24 DOI:10.7771/2157-9288.1163

C. A. Mathis, Emilie A. Siverling, Aran W. Glancy, T. Moore

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引用次数: 27

Abstract

One of the fundamental practices identified in Next Generation Science Standards (NGSS) is argumentation, which has been researched in P-12 science education for the previous two decades but has yet to be studied within the context of P-12 engineering education. This research explores how elementary and middle school science teachers incorporated argumentation into engineering designbased STEM (science, technology, engineering, and mathematics) integration curricular units they developed during a professional development program. To gain a better understanding of how teachers included argumentation in their curricula, a multiple case study approach was conducted using four STEM integration units. While evidence of argumentation was found in each curriculum, the degree to which it appeared in each case varied. The strongest potential for argumentation occurred when students were required to explain and justify their final engineering design solutions to the client; certain guiding questions and discussions also promoted argumentation, depending on their structure. Additionally, argumentation was found to support engineering concepts such as the process of design, engineering thinking, communication in engineering contexts, and the application of science, mathematics, and engineering content. These findings support the idea that argumentation can be integrated into P-12 engineering education contexts in order to support students’ STEM learning.

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STEM整合课程中教师运用论证支持工程学习

在下一代科学标准(NGSS)中确定的基本实践之一是论证，这在过去二十年中已经在P-12科学教育中进行了研究，但尚未在P-12工程教育的背景下进行研究。本研究探讨了中小学科学教师如何将论证融入他们在专业发展计划中开发的基于工程设计的STEM(科学、技术、工程和数学)综合课程单元。为了更好地了解教师如何将论证纳入他们的课程，使用四个STEM整合单元进行了多案例研究方法。虽然在每个课程中都发现了论证的证据，但它在每种情况下出现的程度各不相同。当学生被要求向客户解释和证明他们最终的工程设计解决方案时，辩论的潜力最大;某些指导性问题和讨论也会促进论证，这取决于它们的结构。此外，论证被发现支持工程概念，如设计过程、工程思维、工程环境中的沟通，以及科学、数学和工程内容的应用。这些发现支持了一种观点，即论证可以融入P-12工程教育背景，以支持学生的STEM学习。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Pre-College Engineering Education Research Social Sciences-Education

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

32 weeks

期刊介绍： The Journal of Pre-College Engineering Education Research (J-PEER) is issued electronically twice a year and serves as a forum and community space for the publication of research and evaluation reports on areas of pre-college STEM education, particularly in engineering. J-PEER targets scholars and practitioners in the new and expanding field of pre-college engineering education. This journal invites authors to submit their original and unpublished work in the form of (1) research papers or (2) shorter practitioner reports in numerous areas of STEM education, with a special emphasis on cross-disciplinary approaches incorporating engineering. J-PEER publishes a wide range of topics, including but not limited to: research articles on elementary and secondary students’ learning; curricular and extracurricular approaches to teaching engineering in elementary and secondary school; professional development of teachers and other school professionals; comparative approaches to curriculum and professional development in engineering education; parents’ attitudes toward engineering; and the learning of engineering in informal settings.