In science, technology, engineering, and mathematics (STEM) education in pre-college, engineering is not the silent "e" anymore. There is an accelerated interest in teaching engineering in all grade levels. Structured engineering programs are emerging in schools as well as in out-of-school settings. Over the last ten years, the number of states in the US including engineering in their K-12 standards has tripled, and this trend will continue to grow with the adoption of the Next Generation Science Standards. The interest in pre-college engineering education stems from three different motivations. First, from a workforce pipeline or pathway perspective, researchers and practitioners are interested in understanding precursors, influential and motivational factors, and the progression of engineering thinking. Second, from a general societal perspective, technological literacy and understanding of the role of engineering and technology is becoming increasingly important for the general populace, and it is more imperative to foster this understanding from a younger age. Third, from a STEM integration and education perspective, engineering processes are used as a context to teach science and math concepts. This book addresses each of these motivations and the diverse means used to engage with them.Designed to be a source of background and inspiration for researchers and practitioners alike, this volume includes contributions on policy, synthesis studies, and research studies to catalyze and inform current efforts to improve pre-college engineering education. The book explores teacher learning and practices, as well as how student learning occurs in both formal settings, such as classrooms, and informal settings, such as homes and museums. This volume also includes chapters on assessing design and creativity.

As the world grows increasingly more reliant on technology, there have been repeated calls for more, and more diverse, engineers, along with other science, technology, engineering, and math (STEM) professionals. From these calls has risen an increased focus on engineering in pre-college education, both in formal and informal learning settings. Along with this increased focus came a corresponding increase in research regarding pre-college engineering education. However, informal engineering experiences are under-studied when compared to formal engineering experiences. This manuscript-style dissertation seeks to provide insight into the literature available about pre-college engineering education and the impact and implications for practice of one informal engineering experience, a Girl Scout engineering badge, on middle schoolers’ engineering identity development. To begin my work, I conducted a systematic literature review. Following established systematic literature review methods, I gathered and synthesized a small body of literature regarding the impact of informal engineering experiences on pre-college students’ engineering identity development. The synthesis revealed that informal experiences appear to have a positive impact on participant’s engineering identity, however, little is known about how the impact may vary by program or participant characteristics. Using these results, directions and recommendations for future research was proposed. For the informal engineering experience, two Girl Scout troops, one which met completely online and one which met in a hybrid setting, completed a Girl Scout engineering badge. Fifteen participants completed pre- and post-interviews, and observations of participants were conducted during the badge activities. In addition, participants completed the Draw-an-Engineer Test before the pre-interview and a modified version of the Draw-an-Engineer Test before the post-interview. Data analysis indicated that there was some growth in both engineering identity and engineering knowledge following the engineering badge experience. However, the impact on engineering identity varied between the two settings (hybrid and online), with participants in the online troop slightly more likely to indicate engineering identity growth. Finally, based on participant outcomes and my experiences with transitioning the in-person badge material into a virtual environment, I generated four concrete recommendations for practitioners who wish to conduct virtual informal engineering experiences. Those recommendations are: 1.) Craft your learning environment to reduce participant barriers, 2.) Be flexible and adapt activities as needed, 3.) Cultivate an environment where struggle and failure are okay, and 4.) Leverage your network and build relationships with the organizations you wish to partner with. Additionally, future work to further develop these recommendations was proposed. These three manuscripts come together to provide insight into engineering identity development through an under-studied area of pre-college engineering education: informal experiences. Through my work, I identified gaps in the literature and opportunities for future work, provided insight into the impact that a Girl Scout engineering badge had on participants, and developed recommendations for practice. Particularly, my work informs how the engineering education field may be able to support engineering identity development in girls, which may ultimately influence women’s participation in the engineering field.

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.

This book addresses engineering learning in early childhood, spanning ages 3 to 8 years. It explores why engineering experiences are important in young children's overall development and how engineering is a core component of early STEM learning, including how engineering education links and supports children's existing experiences in science, mathematics, and design and technology, both before school and in the early school years. Promoting STEM education across the school years is a key goal of many nations, with the realization that building STEM skills required by societies takes time and needs to begin as early as possible. Despite calls from national and international organisations, the inclusion of engineering-based learning within elementary and primary school programs remains limited in many countries. Engineering experiences for young children in the pre-school or early school years has received almost no attention, even though young children can be considered natural engineers. This book addresses this void by exposing what we know about engineering for young learners, including their capabilities for solving engineering-based problems and the (few) existing programs that are capitalising on their potential.

Engineering Instruction for High-Ability Learners in K-8 Classrooms is an application-based practitioners' guide to applied engineering that is grounded in engineering practices found in the new Next Generation Science Standards (NGSS) and the Standards for Engineering Education. The book provides educators with information and examples on integrating engineering into existing and newly designed curriculum. The book specifies necessary components of engineering curriculum and instruction, recommends appropriate activities to encourage problem solving, creativity, and innovation, and provides examples of innovative technology in engineering curriculum and instruction. Additionally, authors discuss professional development practices to best prepare teachers for engineering instruction and provide recommendations to identify engineering talent among K-8 students. Finally, the book includes a wealth of resources, including sample lesson and assessment plans, to assist educators in integrating engineering into their curriculum and instruction.

Deeper learning, dialogic learning, and critical thinking are essential capabilities in the 21st-century environments we now operate. Apart from being important in themselves, they are also crucial in enabling the acquisition of many other 21st-century skills/capabilities such as problem solving, collaborative learning, innovation, information and media literacy, and so on. However, the majority of teachers in schools and instructors in higher education are inadequately prepared for the task of promoting deeper learning, dialogic learning, and critical thinking in their students. This is despite the fact that there are educational researchers who are developing and evaluating strategies for such promotion. The problem is bridging the gap between the educational researchers’ work and what gets conveyed to teachers and instructors as evidence-based, usable strategies. This book addresses that gap: in it, leading scholars from around the world describe strategies they have developed for successfully cultivating students’ capabilities for deeper learning and transfer of what they learn, dialogic learning and effective communication, and critical thought. They explore connections in the promotion of these capabilities, and they provide, in accessible form, research evidence demonstrating the efficacy of the strategies. They also discuss answers to the questions of how and why the strategies work. A seminal resource, this book creates tangible links between innovative educational research and classroom teaching practices to address the all-important question of how we can realize our ideals for education in the 21st century. It is a must read for pre-service and in-service teachers, teacher educators and professional developers, and educational researchers who truly care that we deliver education that will prepare and serve students for life.

This book addresses the point of intersection between cognition, metacognition, and culture in learning and teaching Science, Technology, Engineering, and Mathematics (STEM). We explore theoretical background and cutting-edge research about how various forms of cognitive and metacognitive instruction may enhance learning and thinking in STEM classrooms from K-12 to university and in different cultures and countries. Over the past several years, STEM education research has witnessed rapid growth, attracting considerable interest among scholars and educators. The book provides an updated collection of studies about cognition, metacognition and culture in the four STEM domains. The field of research, cognition and metacognition in STEM education still suffers from ambiguity in meanings of key concepts that various researchers use. This book is organized according to a unique manner: Each chapter features one of the four STEM domains and one of the three themes—cognition, metacognition, and culture—and defines key concepts. This matrix-type organization opens a new path to knowledge in STEM education and facilitates its understanding. The discussion at the end of the book integrates these definitions for analyzing and mapping the STEM education research. Chapter 4 is available open access under a Creative Commons Attribution 4.0 International License via link.springer.com