Developing and implementing an Einsteinian science curriculum from years 3–10: A. Concepts, rationale and learning outcomes

Q3 Social Sciences

Physics Education Pub Date : 2024-09-12 DOI:10.1088/1361-6552/ad66a7

Tejinder Kaur, Magdalena Kersting, David Blair, Kyla Adams, David Treagust, Jesse Santoso, Anastasia Lonshakova, Shon Boublil, Marjan Zadnik, Li Ju, David Wood, Elaine Horne and Darren McGoran

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引用次数: 0

Abstract

There has been a growing realisation that school science curricula do not adequately reflect the revolutionary changes in our scientific understanding of the 20th century. This discrepancy between current school education and our modern scientific understanding has led to calls for the modernisation of the science curriculum. Although there have been attempts to introduce topics of Einsteinian physics (i.e. quantum physics and relativity) to school education, often at the secondary level, we still lack a seamless curriculum in which modern science concepts are gradually introduced in primary and middle schools. Guided by the Model of Educational Reconstruction and following a mixed-methods research design, the Einstein-First project aims to address this gap. Einstein-First has developed and implemented an Einsteinian curriculum from Years 3–10 (students aged 7–16) that resolves the disconnect between science in schools and modern scientific understanding. This paper presents the concepts and rationale for the Einstein-First learning approach, as well as a summary of learning outcomes in six Australian schools with 315 students across Years 3–10. Our generally positive findings lay the foundation for informed curriculum development and school education that provides all students with awareness and appreciation of the fundamental concepts that underpin the technologies of the modern world.

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开发和实施 3-10 年级爱因斯坦科学课程： A. 概念、原理和学习成果

越来越多的人意识到，学校的科学课程没有充分反映出我们对 20 世纪科学理解的革命性变化。目前的学校教育与我们对现代科学的理解之间的这种差异，导致了对科学课程现代化的呼声。尽管已经有人尝试在学校教育中引入爱因斯坦物理学（即量子物理学和相对论）的主题，而且通常是在中学阶段，但我们仍然缺乏一个在小学和初中逐步引入现代科学概念的无缝课程。在 "教育重建模式 "的指导下，"爱因斯坦第一 "项目采用混合方法研究设计，旨在弥补这一不足。爱因斯坦第一项目开发并实施了爱因斯坦课程，从 3 年级到 10 年级（学生年龄为 7-16 岁），解决了学校科学与现代科学理解之间的脱节问题。本文介绍了 "爱因斯坦第一 "学习方法的概念和原理，以及澳大利亚六所学校 3-10 年级 315 名学生的学习成果摘要。我们的研究结果总体上是积极的，这为明智的课程开发和学校教育奠定了基础，使所有学生都能认识和理解支撑现代世界技术的基本概念。

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

Physics Education Social Sciences-Education

CiteScore

1.50

自引率

0.00%

发文量

195

期刊介绍： Physics Education seeks to serve the physics teaching community and we welcome contributions from teachers. We seek to support the teaching of physics to students aged 11 up to introductory undergraduate level. We aim to provide professional development and support for teachers of physics around the world by providing: a forum for practising teachers to make an active contribution to the physics teaching community; knowledge updates in physics, educational research and relevant wider curriculum developments; and strategies for teaching and classroom management that will engage and motivate students.