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Creating Project-Based STEM Environments: The REAL Way PDF

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Jennifer Wilhelm · Ronald Wilhelm  Merryn Cole Creating Project- Based STEM Environments The REAL Way Creating Project-Based STEM Environments Jennifer Wilhelm • Ronald Wilhelm Merryn Cole Creating Project-Based STEM Environments The REAL Way Jennifer Wilhelm Ronald Wilhelm Department of STEM Education Department of Physics & Astronomy University of Kentucky University of Kentucky Lexington, KY, USA Lexington, KY, USA Merryn Cole Department of Teaching and Learning University of Nevada Las Vegas Las Vegas, NV, USA ISBN 978-3-030-04951-5 ISBN 978-3-030-04952-2 (eBook) https://doi.org/10.1007/978-3-030-04952-2 Library of Congress Control Number: 2018962874 © Springer Nature Switzerland AG 2019 This work is subject to copyright. All rights are reserved by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. The publisher, the authors, and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authors or the editors give a warranty, express or implied, with respect to the material contained herein or for any errors or omissions that may have been made. The publisher remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. This Springer imprint is published by the registered company Springer Nature Switzerland AG The registered company address is: Gewerbestrasse 11, 6330 Cham, Switzerland Foreword Thankfully, project-based instruction (PBI) is having another resurgence. In the United States, we had one during the progressive era. We had another in the 1990s. And we are having one now, in the second decade of the twenty-first century. Science education has been a major player in each one of these waves of resurgence. The PBI wave today differs in a couple of important ways from our previous history. One difference today is the global interest in the cluster of disciplines we now refer to as “STEM” (science, technology, engineering, and mathematics), and the accom- panying inter- and transdisciplinary possibilities we see for education and for pro- fessional work. A second difference, at least in the United States, is the continuing importance of the standards movement. Of particular note is the emergence of the Next-Generation Science Standards (NGSS Lead States, 2013) that are based on the Framework for K-12 Science Education’s (National Research Council, 2012) ground-breaking conceptualization of the importance of “three-dimensional” learn- ing which combine practices, disciplinary core ideas, and cross-cutting concepts. Creating Project-Based STEM Environments is a timely and important book given this current historical moment. I appreciate Jennifer Wilhelm, Ron Wilhelm, and Merryn Cole’s contribution in this book for multiple reasons. I will focus in this foreword on how “the REAL way” they describe in this volume provides guidance and fodder to help those of us who care about and work in STEM education create a more thriving educational ecosystem for student engagement and learning. Wilhelm, Wilhelm, and Cole, through their PBI curriculum development work as well as their research with teachers and students reported on here, provide us with important new resources in the age of STEM education and NGSS. They seamlessly connect research and prac- tice, and have constructed a volume which should be of use to not only pre-service and in-service teachers and teacher educators, but also to educational researchers. As noted in this text, I began my journey of research and development in project- based instruction through an examination of one ambitious high school earth sci- ence teacher’s efforts (Polman, 2000). For the past 20 years, I have been working with other educators both within and beyond the STEM fields (i.e., also in history and English Language Arts) to design and realize engaging and productive project- v vi Foreword based learning environments. Rory Wagner’s approach provided numerous lessons for other teachers, but it was not a model that everyone could take up. As with the teachers whose instruction is described in this volume, the teachers with whom I have worked face a number of challenges. I have found that teachers are universally attracted to project-based instruction because it may help them enact more engaging learning environments. But they are daunted by how they can manage the time it takes as a teacher to prepare PBI units, and how they can rigorously support stan- dards-based instruction and learning in their disciplines. In science and engineering, the emergence of NGSS has provided guidance on what to aim for, but not how to pull it off. Now that this book is available, I recommend that STEM teacher educa- tors and STEM teachers use it as a means to find their way. Here are some of the insights I find so valuable in Creating Project-Based STEM Environments. Just as students benefit from more highly scaffolded instruction when they encounter a new way of learning such as PBI, teachers will benefit from well- designed, comprehensive curricular units which they can adapt and implement. The Realistic Explorations in Astronomical Learning (REAL) unit (Chap. 5) and the Chemical Reactions Engineered to Address Thermal Energy Situations (CREATES) unit (Chap. 6) have the kind of coherence and scaffolding that are ideal. They make explicit connections to NGSS and Common Core standards. Their levels of STEM integration are impressive as well. They engage students in science practices such as modeling; engineering practices such as designing, creating, testing, and redesign- ing a device (here, a chemical hot or cold pack); and mathematical practices such as using ratios, all while embedding substantive technology use such as modeling soft- ware. These units challenge students to understand and use disciplinary core ideas such as the reasons for the seasons and the conservation of matter in chemical reac- tions, along with cross-cutting concepts such as finding patterns. And they do so while fulfilling purposes that are meaningful not just to the teacher, but to students whose curiosity and agency is awakened. In addition, I am impressed with the design features that inform not only the REAL and CREATES projects, but also the examples created by teachers from the Spanning Astronomical and Atomic Spaces (SAAS) project in Chap. 8. First of all, Wilhelm, Wilhelm, and Cole’s model makes the important addition of the “sub- driving question” to Joe Krajcik and colleagues’ idea of constructing PBI units based on teacher-selected driving questions (e.g., Krajcik & Czerniak, 2014). Interesting and challenging teacher-designated driving questions like “Why does the Moon’s appearance always seem to change?” in REAL and “How can I use chemical reactions to keep me comfortable?” in CREATES allow the teacher to organize a coherent set of thematic lessons that build student knowledge and pre- pare them for more ambitious challenges. Importantly, the overall driving questions are constructed such that students are challenged to construct and then investigate “sub-driving questions” later on in the unit. The benchmark lessons and more teacher-directed portions of the unit thus provide the basis on which students can more effectively drive their culminating project, because they have built up back- ground knowledge and confronted or disrupted misconceptions. In addition, the Foreword vii “REAL way” described in this book involves two structural features in how activity is organized. Each of the lessons on the 5E structure (Engage, Explore, Explain, Elaborate, Evaluate; Bybee, et al., 2006) provides a language and set of routines to make daily work productive. The “REAL way” also integrates milestones through- out, to ensure that routine assessments could be made and revisions and corrections implemented to support student success (Polman, 2000). I believe that Wilhelm, Wilhelm, and Cole’s model, based on this unique combination of existing PBI ideas and the innovation of “sub-driving questions,” is powerful and scalable. I sincerely hope that more teachers and curriculum developers use the model to construct a growing set of project units. Speaking of growing, I want to return to the idea of this book as an important resource for cultivating an ecosystem for project-based instruction, with local habi- tats for learners to blossom through PBI. The accounts and testimonies of the teach- ers in this book who participated in the PBI professional development demonstrate how important their community was to supporting the work. The excitement and success at one middle school where eight of the nine science teachers implemented PBI was indicative of what more widespread reform could be like for teachers and students. As long as ambitious PBI teachers are in the minority at their schools, new groups of students will struggle to adjust each year. With repeated cycles across the year, Wilhelm, Wilhelm, and Cole as well as other research on PBI has shown that many students who historically perform at high levels in school as well as students who historically struggle can begin to thrive. Imagine a world where students like the young woman described in Chap. 7 have multiple years of opportunity to make breakthroughs in how they see themselves, and how they see what it means to learn science. Through the work of her teachers, this young woman moved through a rich habitat for science learning that spanned 6th through 8th grades. It was only at the end of 8th grade that she eventually overcame “her fear of making a mistake and not knowing the right answer”; no doubt, her prior experience of school had led to a limited view of what learning science could be like. I sincerely hope that a growing community of educators take up the ideas in Creating Project-Based STEM Environments and create a widespread ecosystem where STEM learning for all can blossom. References Bybee, R., et al. (2006). The BSCS 5E instructional model: Origins and effective- ness. Colorado Springs, CO: BSCS. Krajcik, J. S., & Czerniak, C. M. (2014). Teaching science in elementary and middle school: A project-based approach (4th Edition). New York: Routledge. National Research Council. (2012). A Framework for K-12 Science Education: Practices, Crosscutting Concepts, and Core Ideas. Committee on a Conceptual Framework for New K-12 Science Education Standards. Board on Science viii Foreword Education, Division of Behavioral and Social Sciences and Education. Washington, DC: The National Academies Press. NGSS Lead States. (2013). Next generation science standards: For states, by states. Washington, DC: The National Academies Press. Available: https://www.next- genscience.org/ Polman, J. L. (2000). Designing project-based science: Connecting learners through guided inquiry. New York: Teachers College Press. Joseph L. Polman Preface My foray into project-based instruction was inspired by three people; this inspiration was also later a catalyst toward our book endeavor. I call these people my three “Jo(e)s” – they are Jo Boaler (author of Experiencing School Mathematics: Traditional and Reform Approaches to Teaching and Their Impact on Student Learning), Joe Polman (author of Designing Project-Based Science: Connecting Learners Through Guided Inquiry), and Joe Krajcik (author of Teaching Science in Elementary and Middle School: A Project-Based Approach). I met Jo Boaler and Joe Polman while I was a graduate student at the University of Texas at Austin. Their work inspired my early research interests and dissertation focus. Shortly thereafter, I met Joe Krajcik when I was a brand-new Assistant Professor at Texas Tech University. The three Jo(e)s influenced how I conducted research, how I taught my methods classes, and how I worked with teachers. After spending my early career producing a body of work on project-based instruction in middle schools and teaching preservice and in-service teachers about how and why project-based instruction would benefit their classrooms, it was time to write a book. I wanted to produce a resource that not only encom- passed my earlier research efforts but also would serve as a model for researchers and teachers to use in their practice. The primary purpose of this book, Creating Project-Based STEM Environments: The REAL Way, is to reveal how STEM classrooms can be purposefully designed for twenty-first-century learners and provide evidence regarding how situated learning experiences will result in more advanced learning. As my research progressed, the other two authors of this book (Ron Wilhelm and Merryn Cole) became involved in this work as well. First was Ron, who was instrumental in the inspiration for and development of the Realistic Explorations in Astronomical Learning (REAL) unit (see Chap. 5). His background as an astronomer influenced the content and design of the unit. He also participated in the professional development of the teachers who implemented REAL in their classrooms. Later, Merryn Cole enrolled in the doctoral program at the University of Kentucky and began research with me. She embraced REAL and project-based instruction, becoming a valuable asset to the research. She authored the Chemical ix x Preface Reactions Engineered to Address Thermal Energy Situations (CREATES) unit to add a second project-based unit to our portfolio to use in middle school classrooms. This book should be of great interest to the STEM education community due to its research to practice approach. The intended audience is preservice and in-ser- vice teachers as well as STEM education researchers. This book models project- based environments that are intentionally designed around the US Common Core State Standards (CCSS, 2010) for Mathematics, the Next Generation Science Standards (NGSS Lead States, 2013) for Science, and the National Educational Technology Standards (ISTE, 2008). This project-based instruction (PBI) resource illustrates how to design and implement interdisciplinary project-based units based on the REAL and CREATES units. The content of the book details these two PBI units with research behind each lesson (including misconceptions students might hold regarding STEM con- tent) and pre-/post-research results of unit implementation with over 40 teachers and thousands of students. In addition to these two units, there are chapters describ- ing how to design one’s own research-based PBI unit and teacher commentaries regarding strategies, obstacles overcome, and successes as they designed and implemented their PBI units for the first time after learning how to create PBI STEM environments the “REAL” way. Lexington, KY, USA Jennifer Wilhelm

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