| Preface |
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xi | |
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1 Introduction: Coordinating PreK-16 STEM Education Research and Practices for Advancing and Refining Reform Agendas |
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1 | (32) |
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33 | (66) |
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2 Thinking about a System and Systems Thinking in Engineering |
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35 | (14) |
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3 Diagnostic Instruction: Toward an Integrated System for Classroom Assessment |
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49 | (19) |
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4 Response 1: Systems Thinking as a Design Problem |
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68 | (13) |
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5 Response 2: Improving Learning about Systems Requires Designing for Change in Educational Systems |
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81 | (18) |
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Poster Presentation I Virtual and Authentic Web-based Ecological Inquiries |
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88 | (11) |
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THEME II Model-Based Reasoning |
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99 | (48) |
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6 Modeling Authentic STEM Research: A Systems Thinking Perspective |
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101 | (14) |
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7 Meeting the Standards for STEM Educations: Individual and National Needs |
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115 | (10) |
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8 Response 1: Model-Based Reasoning in Professional Development |
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125 | (6) |
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9 Response 2: "Where Is the Line?" |
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131 | (16) |
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Poster Presentation II Cultivating Systems Thinking and Engagement through an Intercollege Minor in Sustainability Leadership |
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142 | (5) |
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THEME III Quantitative Reasoning |
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147 | (56) |
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10 Quantitative Reasoning in Mathematics Education: Directions in Research and Practice |
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149 | (18) |
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11 Teachers' Use of Data, Measurement, and Data Modeling in Quantitative Reasoning |
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167 | (14) |
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12 Response 1: Quantitative Reasoning in STEM Disciplines |
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181 | (8) |
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13 Response 2: Quantitative Reasoning: Capturing a Tension Between Structure and Variability |
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189 | (14) |
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Poster Presentation III Fundamentals of Climate Science |
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194 | (9) |
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THEME IV Equity, Epistemic, and Ethical Outcomes |
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203 | (48) |
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14 Educational and Ethical Dilemmas for STEM Education in Pennsylvania's Marcellus Shale Gasfield Communities |
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205 | (10) |
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15 Defining a Knowledge Base for Reasoning in Science: The Role of Procedural and Epistemic Knowledge |
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215 | (17) |
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16 Response 1: Views from Above and Below: Access to Science Education |
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232 | (5) |
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17 Response 2: The Values of Science Literacy |
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237 | (14) |
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Poster Presentation IV Fossil Mammals and Biotic Response to Climate Change |
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243 | (8) |
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THEME V STEM Communication and Policy Outreach |
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251 | (50) |
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18 Why People Care About Chickens and Other Lessons about Rhetoric, Public Science, and Informal Learning Environments |
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253 | (18) |
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19 New Environments for Professional Development: Situating Science Learning and Teaching in a Framework and NGSS World |
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271 | (11) |
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20 Response 1: School-System Contexts for Professional Development |
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282 | (7) |
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21 Response 2: Technology-supported Communication in Science: Conjectures on Expertise and Evaluation |
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289 | (12) |
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301 | (27) |
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22 Reflections on the Waterbury Summit: STEAM and Systems Thinking |
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303 | (4) |
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23 Summary: Driving Change Forward |
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307 | (21) |
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| About the Authors |
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328 | (11) |
| Waterbury Summit Participants |
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339 | (6) |
| Index |
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345 | |
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