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This text contains 25 Project-Based Learning (PBL) lessons written by a combination of undergraduate preservice teachers, inservice teachers, and graduate students. Everyone who wrote a chapter strives to improve STEM education to help others implement standards-based STEM instruction that takes learning in isolation to greater accountability through integrated and meaningful tasks that answer the question every teacher dreads: When am I going to use this? The PBLs were written to implement in middle and high-school classrooms. All of them are interdisciplinary in nature. We have divided them into six themes: construction and design, water, environment, mixtures, technology, nutrition and genetics. Each lesson contains a “schedule at a glance” and the “well-defined outcome” so you can quickly see how a particular PBL fits into your curriculum. Objectives are listed along with STEM connections written as objectives. We have included all materials needed and then each day of activities including an imbedded engagement, exploration, explanation, evaluation (including rubrics), and extension. We have tried to include everything necessary for successful implementation. This practical book is the perfect companion to the handbook for learning about implementing PBLs: Project-Based Learning: An Integrated Science, Technology, Engineering, and Mathematics (STEM) Approach – second edition.
Twenty-five interdisciplinary project-based learning lessons for middle and high school classrooms.
This second edition of Project-Based Learning (PBL) presents an original approach to Science, Technology, Engineering and Mathematics (STEM) centric PBL. We define PBL as an “ill-defined task with a well-defined outcome,” which is consistent with our engineering design philosophy and the accountability highlighted in a standards-based environment. This model emphasizes a backward design that is initiated by well-defined outcomes, tied to local, state, or national standard that provide teachers with a framework guiding students’ design, solving, or completion of ill-defined tasks. This book was designed for middle and secondary teachers who want to improve engagement and provide contextualized learning for their students. However, the nature and scope of the content covered in the 14 chapters are appropriate for preservice teachers as well as for advanced graduate method courses. New to this edition is revised and expanded coverage of STEM PBL, including implementing STEM PBL with English Language Learners and the use of technology in PBL. The book also includes many new teacher-friendly forms, such as advanced organizers, team contracts for STEM PBL, and rubrics for assessing PBL in a larger format.
STEM Teaching: An Interdisciplinary Approach breaks from the more historical idea of making knowledge within disciplines and seeks to engage the reader in a growing conversation that is gaining momentum and is focused on an ‘interdisciplinarity of STEM education’, which seeks to embrace and/or present emerging perspectives on the standards. Importantly, the conversation on STEM education and interdisciplinary approaches to teacher preparation may draw into specific relief the respective professional and/or disciplinary standards for each of the four STEM disciplines as each relates to fostering an interdisciplinary approach. The importance and relevance of this interdisciplinary perspective to teacher preparation lies in the realization that STEM literacy moves into everyday lives and thinking, and not just in STEM related disciplines. This means that faculty in teacher preparation need to extend the range of STEM literacy in pedagogical strategies so that STEM teaching is enriched with multimodal literacies into teaching and learning, which in turn makes STEM knowledge more relevant and engaging for its manifest connections to solving the problems that challenge society.
This book models project-based environments that are intentionally designed around the United States 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). The primary purpose of this book is to reveal how middle school STEM classrooms can be purposefully designed for 21st Century learners and provide evidence regarding how situated learning experiences will result in more advanced learning. This Project-Based Instruction (PBI) resource illustrates how to design and implement interdisciplinary project-based units based on the REAL (Realistic Explorations in Astronomical Learning – Unit 1) and CREATES (Chemical Reactions Engineered to Address Thermal Energy Situations – Unit 2). The content of the book details these two PBI units with authentic student work, explanations and research behind each lesson (including misconceptions students might hold regarding STEM content), pre/post research results of unit implementation with over 40 teachers and thousands of students. In addition to these two units, there are chapters describing how to design one’s own research-based PBI units incorporating 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.
This book highlights models for promoting interdisciplinary thinking and an appreciation for interdisciplinary understanding among students in STEM-related fields. Students majoring in science, technology, engineering, and mathematics often perceive that courses in their major are not related to the general education liberal arts courses required for their degrees. This separation prevents the transfer of skills between their general education courses and their degree pursuits. The false dichotomy is particularly important because solving the daunting challenges of the twenty-first century—such as drug-resistant bacteria, scarcity of natural resources, and climate change—requires global citizens armed with robust, complex abilities who can integrate interdisciplinary concepts with bold technologies. Contributors to this book explore ways in which this dichotomy can be overcome.
Pre-university engineering education has become the topic of increasing interest in technology education circles. It can provide content for the E in STEM (Science, Technology, Engineering and Mathematics) education, which is in the interest of technology educators at different educational levels as it builds the bridge between them and the science and mathematics educators. In this book goals for pre-university engineering education are explored as well as existing practices from a variety of countries. The coming years will show if pre-university engineering education will catch on. The trend towards STEM integrated education that today can be seen in many countries will certainly create a further need and stimulus for that to happen. Hopefully this book can contribute to such a development of both formal and informal K-12 engineering education. Not only for preparing the next generation of engineers, but also for the technological literacy of future citizens.
Cultural Impact on Conflict Management in Higher Education shares information regarding conflict management and resolution in higher education from a global perspective. In this book, we introduced many conflict resolution methods from different regions in the world. You can borrow some successful strategies and examine the differences and similarities between contexts. The book shares a conflict resolution model which may direct the reader to start thinking about addressing and managing conflicts from different levels of organizations. This book is a collective work of authors coming from all over the world. We chose higher education as the context because it is a place where diverse thoughts, perspectives, and people come together. Because of the potential richness of diversity on a college campus, the opportunity for conflicts occurs. Managing conflict does not work when there is a “one-way only approach/model” for addressing conflict. Some conflict resolution encompasses multiple dimensions: (a) one’s personal beliefs or beliefs about an issue; (b) an individual’s personal history in terms of how the conflict was perceived as something to be discussed or not; (c) work culture of the conflict where if ‘one has a conflict,’ the person or unit is messing up or there is a problem person; (d) the unconscious strategies of ‘face saving’ (trying to maintain one’s image) present; (e) social hierarchies or relationships; and (f) the diversity dimensions and issues that may be present.
This book provides an international platform for educators from different STEM disciplines to present, discuss, connect, and develop collaborations in two inter-related ways: (1) sharing and discussing changes and innovations in individual discipline-based education in STEM/STEAM, and (2) sharing and discussing the development of interdisciplinary STEM/STEAM education. Possible relationships and connections between individual disciplines (like mathematics or physics) and STEM education remain under explored and the integration of traditionally individual discipline-based education in STEM education is far from balanced. Efforts to pursue possible connections among traditionally separated individual disciplines in STEM are not only necessary for the importance of deepening and expanding interdisciplinary research and education in STEM, but also for the ever-increasing need of reflecting on and changing how traditional school subjects (like mathematics or physics) can and should be viewed, taught, and learned. Scholars from eight countries/regions provide diverse perspectives and approaches on changes and innovations in STEM disciplinary and interdisciplinary education. Disciplinary and Interdisciplinary Education in STEM will be a great resource to students and researchers in STEM education as well as STEM curriculum developers and teacher educators internationally.
Teaching Science in Elementary and Middle School offers in-depth information about the fundamental features of project-based science and strategies for implementing the approach. In project-based science classrooms students investigate, use technology, develop artifacts, collaborate, and make products to show what they have learned. Paralleling what scientists do, project-based science represents the essence of inquiry and the nature of science. Because project-based science is a method aligned with what is known about how to help all children learn science, it not only helps students learn science more thoroughly and deeply, it also helps them experience the joy of doing science. Project-based science embodies the principles in A Framework for K-12 Science Education and the Next Generation Science Standards. Blending principles of learning and motivation with practical teaching ideas, this text shows how project-based learning is related to ideas in the Framework and provides concrete strategies for meeting its goals. Features include long-term, interdisciplinary, student-centered lessons; scenarios; learning activities, and "Connecting to Framework for K–12 Science Education" textboxes. More concise than previous editions, the Fourth Edition offers a wealth of supplementary material on a new Companion Website, including many videos showing a teacher and class in a project environment.