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Materials Similar to Improved Student Performance in Electricity and Magnetism Following Prior MAPS Instruction in Mechanics

• 39%: Effect of explicit problem solving instruction on high school students' problem-solving performance and conceptual understanding of physics
• 34%: Student Performance in a Keller-Plan Course in Introductory Electricity and Magnetism
• 34%: Link maps and map meetings: Scaffolding student learning
• 34%: Facilitating Students’ Problem Solving across Multiple Representations in Introductory Mechanics
• 34%: Teaching assistants' performance at identifying common introductory student difficulties revealed by the conceptual survey of electricity and magnetism
• 33%: Assessing student expertise in introductory physics with isomorphic problems. I. Performance on nonintuitive problem pair from introductory physics
• 33%: An Exploratory Qualitative Study of the Proximal Goal Setting of Two Introductory Modeling Instruction Physics Students
• 33%: The impact of social integration on student persistence in introductory Modeling Instruction courses
• 32%: Improving Students' Understanding of Electricity and Magnetism
• 31%: Modeling instruction in mechanics
• 31%: Student understanding of quantum mechanics at the beginning of graduate instruction
• 31%: Resource Letter ALIP–1: Active-Learning Instruction in Physics
• 31%: Model-based inquiry vs. Traditional computer simulation-based instruction: Which can better help students construct the quantum-mechanical model of an atom?
• 31%: Measuring Model-Based High School Science Instruction: Development and Application of a Student Survey
• 31%: Multiple Modes of Reasoning in Physics Problem Solving, with Implications for Instruction
• 31%: Improving students' understanding of quantum mechanics by using peer instruction tools
• 31%: Beyond performance metrics: Examining a decrease in students’ physics self-efficacy through a social networks lens
• 31%: Assessing students’ conceptual knowledge of electricity and magnetism
• 29%: Development and validation of a sequence of clicker questions for helping students learn addition of angular momentum in quantum mechanics