This resource presents a one-page summary of the methods, results, and conclusions from a comprehensive literature review of 137 pieces of literature addressing the intersections of imagination and STEM. The research questions guiding this comprehensive literature review were: (a) What types of literature address imagination in STEM (science, technology, engineering, and math) education and practice? (b) How does the literature define imagination? (c) How does the literature position the role of imagination in STEM? Details of the literature review results can be found summarized in other
A brief summary of the results of an analysis of 137 pieces of literature reviewed as part of the project’s comprehensive literature review, focusing specifically on the range of ways imagination is positioned in relation to STEM (as a trait or capability, an outcome, a process, a theoretical framework, or as valuable).
This resource presents a list of categories of “imaginative ways of thinking” as well as word clouds illustrating the huge range of ways imagination is described in literature at the intersections of imagination and STEM. This resource reflects results from a comprehensive review of 137 pieces of literature addressing the intersections of imagination and STEM.
The National Network for Ocean and Climate Change Interpretation [NNOCCI] is a Community of Practice [CoP] dedicated to advancing the conversation on climate change, based on the principle that wide-scale training with proven communication techniques can change the national discourse around climate change to be more productive, creative, and solutions-focused.
NNOCCI CoP is a network of individuals and organizations in formal and informal education, the social sciences, climate sciences, and public policy. By 2018, the community represented more than 184 institutions in 38 states, and over
Abstract STEM education programs are often formulated with a "hands-on activities" focus across a wide array of topics from robotics to rockets to ecology. Traditionally, the impact of these programs is based on surveys of youth on program-specific experiences or the youths’ interest and impressions of science in general. In this manuscript, we offer a new approach to analyzing science programming design and youth participant impact. The conceptual framework discussed here concentrates on the organization and analysis of common learning activities and instructional strategies. We establish
Developing a growth mindset has been identified as a key strategy for increasing youth achievement, motivation, and resiliency (Rattan et al. 2015). At its core, growth mindset describes the idea that one’s abilities can change through using new learning strategies and receiving appropriate mentoring (Dweck 2008). In contrast, a fixed mindset relates to the idea that ability is inherent and cannot be changed. We have taken up the concept of growth mindset and developed it specifically for the context of STEAM (science, technology, engineering, art, and math), a growing area of focus in both in
This research examines the Tree Investigators project to support science learning with mobile devices during family public programmes in an arboretum. Using a case study methodology, researchers analysed video records of 10 families (25 people) using mobile technologies with naturalists at an arboretum to understand how mobile devices supported science talk related to tree biodiversity. The conceptual framework brings together research on technological supports for science learning and research on strategies that encourage families to engage in conversations that support observation and
The paper presents and discusses the Research and Development and related reflective practice process for the design of an approach to STEM school education. It focuses on Future Inventors, an education project of the National Museum of Science and Technology Leonardo da Vinci which aims to design, develop, test, and define an approach for teaching and learning in STEM at junior high school. Through this case study, the authors argue for the need to design for learning activities in which children can learn creatively building on their own potential and, for educators, to develop and maintain
Environmental educators have used guided-inquiry in natural and supportive learning environments for decades, but comparatively little programming and research has focused on experiences in urban environments, including in constructed ecosystems like green roofs, or impacts on older youth and adults. To address this gap, we designed a tiered, near-peer research mentoring program called Project TRUE (Teens Researching Urban Ecology) and used a mixed-methods approach to evaluate impacts on undergraduates serving as research mentors. During the 11-week program, undergraduates conducted
Science fairs have a remarkable hold on the public’s attention. President Obama, in his 2011 State of the Union address, said, “We need to teach our kids that it’s not just the winner of the Super Bowl who deserves to be celebrated, but the winner of the science fair.” The 2018 film Science Fair won that year’s Sundance Film Festival favorite award. The 2018 book The Class chronicled a year in a classroom where science fairs are at the center of science education. And a recent GEICO “Science Fair of the Future” television commercial had more than 11 million views on YouTube in its first month
Science fairs offer potential opportunities for students to learn first-hand about the practices of science. Over the past six years we have been carrying out voluntary and anonymous surveys with regional and national groups of high school and post high school students to learn about their high school science fair experiences regarding help received, obstacles encountered, and opinions about the value and impact of science fair. Understanding what students think about science fairs will help educators make science fairs more effective learning opportunities. In this paper, we focus on the
The goal of our ongoing research is to identify strengths and weaknesses of high school level science fair and improvements that can help science educators make science fair a more effective, inclusive and equitable learning experience. In this paper, we confirm and extend our previous findings in several important ways. We added new questions to our anonymous and voluntary surveys to learn the extent to which students had an interest in science or engineering careers and if science fair participation increased their interest in science or engineering. And we surveyed a national rather than