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Materials Similar to Making and Breaking Bones: Learning Physics through Engineering Design

• 49%: Impact of Argumentation Scaffolds in Contrasting Designs Tasks on Elementary Pre-Service Teachers' Use of Science Ideas in Engineering Design
• 49%: Design Principles to Support Physics and Engineering Learning in Complementary Classrooms and Field Trip Activities
• 43%: Improving Engineering Students’ Design Skills in a Project-Based Learning Course by Addressing Epistemological Issues
• 39%: Dynaturtle Revisited: Learning Physics Through Collaborative Design of a Computer Model
• 37%: Designing online learning modules to conduct pre- and post-testing at high frequency
• 37%: Design-based research project to develop a science and engineering education program linking field trip experiences to classroom experiences.
• 37%: A framework for classifying opportunities to learn in Faculty Online Learning Communities: A preview with sample application
• 36%: Student learning of critical circuits concepts in physics and engineering*
• 36%: Using Observations of Universal Design for Learning to Enhance Post-secondary STEM Teaching Practices
• 35%: Learning logs: A Classroom Practice for Enhancing Scientific Sense Making
• 35%: Investigative Science Learning Environment: Using the processes of science and cognitive strategies to learn physics
• 35%: Improving Learning for Underrepresented Groups in Physics for Engineering Majors
• 35%: Using Johnson-Laird's cognitive framework of sense-making to characterize engineering students' mental representations in kinematics
• 35%: A framework for curriculum design to support mathematical sense making
• 34%: Supporting learning and promoting conceptual change with box and AVOW diagrams. Part 1: Representational design and instructional approaches
• 34%: Investigation of Student Learning in Thermodynamics and Implications for Instruction in Chemistry and Engineering
• 34%: Reforming a large lecture modern physics course for engineering majors using a PER-based design
• 34%: Design and reflection help students develop scientific abilities: Learning in introductory physics laboratories
• 34%: The impact of problem-based learning on engineering students’ beliefs about physics and conceptual understanding of energy and momentum