Three dimensional or 3D printing technology is a process of making three dimensional solid objects from a digital file. Currently, low cost and affordable 3D printers enable teachers, schools, and higher education institutions to make 3D printing a part of the curriculum. Integrating 3D printing into the curriculum provides an opportunity for students to collaboratively discuss, design, and create 3D objects. The literature reveals that there are numerous advantages of integrating 3D printing into teaching and learning. Educators recommend that 3D printing should be introduced to the students at a young age to teach STEM concepts, develop creativity and engage in team work – essential skills for the 21st century work force.
This edited volume documents recent attempts to integrate 3D printing into the curriculum in schools and universities and research on its efficacies and usefulness from the practitioners' perspectives. It unveils the exemplary works by educators and researchers in the field highlighting the current trends, theoretical and practical aspects of 3D printing in teaching and learning.
Contributors are: Waleed K. Ahmed, Issah M. Alhamad, Hayder Z. Ali, Nagla Ali, Hamad AlJassmi,Jason Beach, Jennifer Buckingham, Michael Buckingham, Dean Cairns, Manisha Dayal, Muhammet Demirbilek, Yujiro Fujiwara, Anneliese Hulme, Myint Swe Khine, Lee Kenneth Jones, Jennifer Loy, Kehui Luo, Elena Novak, James I. Novak, Joshua Pearce, Dorothy Belle Poli, Chelsea Schelly, Min Jeong Song, Sylvia Stavridi, Lisa Stoneman, Goran Štrkalj, Mirjana Štrkalj, Pamela Sullivan, Jeremy Wendt, Stephanie Wendt, and Sonya Wisdom.
This volume of the
World of Science Education gathers contributions from Latin American science education researchers covering a variety of topics that will be of interest to educators and researchers all around the world. The volume provides an overview of research in Latin America, and most of the chapters report findings from studies seldom available for Anglophone readers. They bring new perspectives, thus, to topics such as science teaching and learning; discourse analysis and argumentation in science education; history, philosophy and sociology of science in science teaching; and science education in non-formal settings. As the Latin American academic communities devoted to science education have been thriving for the last four decades, the volume brings an opportunity for researchers from other regions to get acquainted with the developments of their educational research. This will bring contributions to scholarly production in science education as well as to teacher education and teaching proposals to be implemented in the classroom.
Why Science and Arts Creativities Matter is a ground-breaking text which significantly extends current understandings of STEAM and debates about individuation of disciplines vis-à-vis transdisciplinary theory. Drawing upon posthumanism, new materialism and enactivism, this collection of chapters aims to dwell further into the ways in which we come to know in relationship with the world. The text draws together a wide set of approaches and points of views to stimulate dialogue and awareness of the different ways in which we can extend the repertoire of human faculties for thinking and experiencing the world. A unique invitation is shared with readers to develop greater understanding of the contribution of education across the arts and sciences and to re-imagine our collective futures.
This book is a unique and timely volume that opens up several new lines of enquiry and arguments on STEAM education. It rebalances and readdresses the current emphasis in the literature around STEAM as another, newer opportunity to teach content. Instead, it brings a more specific focus on an entwining of contemporary theorists – putting theory to work – to extend the means for understanding and cultivating science and arts creativities, and make explicit key connections with the materiality of practices. This new go-to text offers a demonstration of how the latest research and theoretically engaged thinking (thinking through theory) on STEAM education can be put to work in practice.
Contributors are: Ramsey Affifi, Sofie Areljung, Chris Brownell, Pamela Burnard, Kerry Chappell, Laura Colucci-Gray, Carolyn Cooke, Kristóf Fenyvesi, Erik Fooladi, Cathy Francis, Lindsay Hetherington, Anna Hickey-Moody, Christine Horn, Tim Ingold, Riikka Kosola, Zsolt Lavicza, Elsa Lee, Saara Lehto, Danielle Lloyd, James Macallister, Caroline Maloney, Tessa Mcgavock, Karin Murris, Lena Nasiakou, Edvin Østergaard, Anne Pirrie, Hermione Ruck Keene, Ruth Sapsed, Diana Scherer, Pallawi Sinha, Margaret Somerville, Keiren Stephenson, Carine Steyn, Jan Van Boeckel, Nicola Walshe, Olivier Werner, Marissa Willcox, and Heather Wren.
The authors provide practical, research-informed, guidelines and detailed lesson plans that improve learning of chemical, physical, biological, and Earth & space sciences. The context for learning is the myriad of exciting opportunities provided by informal science institutions such as zoos, museums, space centers and the outdoors. Many such institutions seek to educate the public and inspire budding scientists. Visits outside school help students relate science to everyday life, providing strong motivation to learn science for all abilities. This book shows the key to making such visits effective, is when they are linked to classroom learning using a learning management system, drawing upon modern students’ fascination with digital technologies and mobile devices.
Jesuits and the Book of Nature: Science and Education in Modern Portugal offers an account of the Jesuits’ contributions to science and education after the restoration of the Society of Jesus in Portugal in 1858. As well as promoting an education grounded on an “alliance between religion and science,” the Portuguese Jesuits founded a scientific journal that played a significant role in the consolidation of taxonomy, plant breeding, biochemistry, and molecular genetics. In this book, Francisco Malta Romeiras argues that the priority the Jesuits placed on the teaching and practice of science was not only a way of continuing a centennial tradition but should also be seen as response to the adverse anticlerical milieu in which the restoration of the Society of Jesus took place.
Attributing Excellence in Medicine discusses the aura around the prestigious Nobel Prize in Physiology or Medicine. It analyzes the social processes and contingent factors leading to recognition and reputation in science and medicine. This volume will help the reader to better understand the dynamics of the attribution of excellence throughout the 20th century.
Contributors are Massimiano Bucchi, Fabio De Sio, Jacalyn Duffin, Heiner Fangerau, Thorsten Halling, Nils Hansson, David S. Jones, Gustav Källstrand, Ulrich Koppitz, Pauline Mattsson, Katarina Nordqvist, Scott H. Podolsky, Thomas Schlich, and Sven Widmalm.
There is a critical need to prepare diverse teachers with expertise in science, technology, engineering, and mathematics (STEM) with the skills necessary to work effectively with underrepresented K-12 students. Three major goals of funded STEM programs are to attract and prepare students at all educational levels to pursue coursework in the STEM content areas, to prepare graduates to pursue careers in STEM fields, and to improve teacher education programs in the STEM content areas. Drawing upon these goals as the framework for
Recruiting, Preparing, and Retaining STEM Teachers for a Global Generation, the 15 chapters contained herein highlight both the challenges and successes of recruiting, preparing, and sustaining novice teachers in the STEM content areas in high-need schools.
Recruiting, retaining and sustaining highly-qualified teachers with expertise in STEM content areas to work in hard-to-staff schools and geographic areas are necessary to equalize educational opportunities for rural and urban Title 1 students. High teacher turnover rates, in combination with teachers working out-of-field, leave many students without highly-qualified teachers in STEM fields. Most of the chapters in this volume were prepared by scholars who received NSF funding through Noyce and are engaged in addressing research questions related to these endeavours.
Contributors are: Lillie R. Albert, Cynthia Anhalt, Saman A. Aryana, Joy Barnes-Johnson, Lora Bartlett, Brezhnev Batres, Diane Bonilla, Patti Brosnan, Andrea C. Burrows, Alan Buss, Laurie O. Campbell, Phil Cantor, Michelle T. Chamberlin, Scott A. Chamberlin, Marta Civil, Lin Ding, Teresa Dunleavy, Belinda P. Edwards, Jennifer A. Eli, Joshua Ellis, Adrian Epps, Anne Even, Angela Frausto, Samantha Heller, Karen E. Irving, Heather Johnson, Nicole M. Joseph, Richard Kitchen, Karen Kuhel, Marina Lazic, Jacqueline Leonard, Rebecca H. McGraw, Daniel Morales-Doyle, Sultana N. Nahar, Justina Ogodo, Anil K. Pradhan, Carolina Salinas, David Segura, Lynette Gayden Thomas, Alisun Thompson, Maria Varelas, Dorothy Y. White, Desha Williams, and Ryan Ziols.
STEM of Desire: Queer Theories and Science Education locates, creates, and investigates intersections of science, technology, engineering, and mathematics (STEM) education and queer theorizing. Manifold desires—personal, political, cultural—produce and animate STEM education. Queer theories instigate and explore (im)possibilities for knowing and being through desires normal and strange. The provocative original manuscripts in this collection draw on queer theories and allied perspectives to trace entanglements of STEM education, sex, sexuality, gender, and desire and to advance constructive critique, creative world-making, and (com)passionate advocacy. Not just another call for inclusion, this volume turns to what and how STEM education and diverse, desiring subjects might be(come) in relation to each other and the world.
STEM of Desire is the first book-length project on queering STEM education. Eighteen chapters and two poems by 27 contributors consider STEM education in schools and universities, museums and other informal learning environments, and everyday life. Subject areas include physical and life sciences, engineering, mathematics, nursing and medicine, environmental education, early childhood education, teacher education, and education standards. These queering orientations to theory, research, and practice will interest STEM teacher educators, teachers and professors, undergraduate and graduate students, scholars, policy makers, and academic libraries.
Contributors are: Jesse Bazzul, Charlotte Boulay, Francis S. Broadway, Erin A. Cech, Steve Fifield, blake m. r. flessas, Andrew Gilbert, Helene Götschel, Emily M. Gray, Kristin L. Gunckel, Joe E. Heimlich, Tommye Hutson, Kathryn L. Kirchgasler, Michelle L. Knaier, Sheri Leafgren, Will Letts, Anna MacDermut, Michael J. Reiss, Donna M. Riley, Cecilia Rodéhn, Scott Sander, Nicholas Santavicca, James Sheldon, Amy E. Slaton, Stephen Witzig, Timothy D. Zimmerman, and Adrian Zongrone.
Critical Issues and Bold Visions for Science Education contains 16 chapters written by 32 authors from 11 countries. The book is intended for a broad audience of teachers, teacher educators, researchers, and policymakers. Interesting perspectives, challenging problems, and fresh solutions grounded in cutting edge theory and research are presented, interrogated, elaborated and, while retaining complexity, offer transformative visions within a context of political tensions, historical legacies, and grand challenges associated with Anthropocene (e.g., sustainability, climate change, mass extinctions).
Within overarching sociocultural frameworks, authors address diverse critical issues using rich theoretical frameworks and methodologies suited to research today and a necessity to make a difference while ensuring that all participants benefit from research and high standards of ethical conduct. The focus of education is broad, encompassing teaching, learning and curriculum in pre-k-12 schools, museums and other informal institutions, community gardens, and cheeseworld. Teaching and learning are considered for a wide range of ages, languages, and nationalities. An important stance that permeates the book is that research is an activity from which all participants learn, benefit, and transform personal and community practices. Transformation is an integral part of research in science education.
Contributors are: Jennifer Adams, Arnau Amat, Lucy Avraamidou, Marcília Elis Barcellos, Alberto Bellocchi, Mitch Bleier, Lynn A. Bryan, Helen Douglass, Colin Hennessy Elliott, Alejandro J. Gallard Martínez, Elisabeth Gonçalves de Souza, Da Yeon Kang, Shakhnoza Kayumova, Shruti Krishnamoorthy, Ralph Levinson, Sonya N. Martin, Jordan McKenzie, Kathy Mills, Catherine Milne, Ashley Morton, Masakata Ogawa, Rebecca Olson, Roger Patulny, Chantal Pouliot, Leah D. Pride, Anton Puvirajah, S. Lizette Ramos de Robles, Kathryn Scantlebury, Glauco S. F. da Silva, Michael Tan, Kenneth Tobin, and Geeta Verma.
Science educators have come to recognize children’s reasoning and problem solving skills as crucial ingredients of scientific literacy. As a consequence, there has been a concurrent, widespread emphasis on argumentation as a way of developing critical and creative minds. Argumentation has been of increasing interest in science education as a means of actively involving students in science and, thereby, as a means of promoting their learning, reasoning, and problem solving. Many approaches to teaching argumentation place primacy on teaching the structure of the argumentative genre prior to and at the beginning of participating in argumentation. Such an approach, however, is unlikely to succeed because to meaningfully learn the structure (grammar) of argumentation, one already needs to be competent in argumentation. This book offers a different approach to children’s argumentation and reasoning based on dialogical relations, as the origin of internal dialogue (inner speech) and higher psychological functions. In this approach, argumentation first exists as dialogical relation, for participants who are in a dialogical relation with others, and who employ argumentation for the purpose of the dialogical relation. With the multimodality of dialogue, this approach expands argumentation into another level of physicality of thinking, reasoning, and problem solving in classrooms. By using empirical data from elementary classrooms, this book explains how argumentation emerges and develops in and from classroom interactions by focusing on thinking and reasoning through/in relations with others and the learning environment.