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Materials Similar to Multiple representations of work-energy processes

• 66%: The Use of Multiple Representations and Visualizations in Student Learning of Introductory Physics: An Example from Work and Energy
• 52%: The Role of Work-energy Bar Charts as a Physical Representation in Problem Solving
• 52%: Facilitating Strategies for Solving Work-Energy Problems in Graphical and Equational Representations
• 44%: An Overview of Recent Research on Multiple Representations
• 41%: Student understanding of the work-energy and impulse-momentum theorems
• 40%: Positive attitudinal shifts with the Physics by Inquiry curriculum across multiple implementations
• 39%: The challenge of matching learning assessments to teaching goals: An example from the work-energy and impulse-momentum theorems
• 38%: Case Study: Students' Use of Multiple Representations in Problem Solving
• 38%: Expert and Novice Use of Multiple Representations During Physics Problem Solving
• 38%: The Influence of Tablet PCs on Students’ Use of Multiple Representations in Lab Reports
• 38%: Student ability to apply the concepts of work and energy to extended systems
• 38%: Multiple-choice test of energy and momentum concepts
• 37%: Comparing Explicit and Implicit Teaching of Multiple Representation Use in Physics Problem Solving
• 37%: Patterns of multiple representation use by experts and novices during physics problem solving
• 37%: Strongly and weakly directed approaches to teaching multiple representation use in physics
• 37%: Facilitating Students’ Problem Solving across Multiple Representations in Introductory Mechanics
• 37%: Negative Energy: Why Interdisciplinary Physics Requires Multiple Ontologies
• 37%: Multiple Representations and Epistemic Games in Introductory Physics Exam Solutions
• 35%: Learning with multiple representations: An example of a revision lesson in mechanics