This is a handout from the session "Introducing your preschool audiences to science and astronomy" at the 2014 ASTC Conference held in Raleigh, NC. The session discussed how the My Sky Tonight project supports informal science educators in engaging young children in the practices of science through astronomy.
This is a handout from the session "Creating Successful Partnerships Between Informal and Formal Science Education" at the 2014 ASTC Conference held in Raleigh, NC. The session discussed several models of collaboration between the formal and informal sectors.
This report provides background information about the Flathead Watershed, the people responsible for funding the project and an depth description of Phase I, the Delphi Survey. The report includes participant information, methodology, data acquisition and findings.
This NSF Special Report highlights broader impacts. Scientific progress comes in all shapes and sizes. Researchers peer at the microscopic gears of genomes, scan the heavens for clues of our origins. They unearth wind-weathered fossils, labor over complex circuitry, guide students through the maze of learning. Disparate fields, researchers and methods united by one thing: potential. Every NSF grant has the potential to not only advance knowledge, but benefit society -- what we call broader impacts. Just like the kaleidoscopic nature of science, broader impacts come in many forms. No matter the
The Flathead Community of Resource Educators (CORE) is a consortium of educators in the Flathead Watershed. They produced the Flathead Watershed Sourcebook as a tool to increase understanding and appreciation of the region. The objective of this project is to produce a curriculum guide to accompany the Sourcebook. This curriculum project will be carried out by a team of experts in interdisciplinary teacher education from Montana State University. The project will be conducted in four phases and include the guidance and feedback of Scientists, Educators, and Resource Managers living and working within the Flathead watershed.
The Ross Sea Project was a Broader Impact projects for an NSF sponsored research mission to the Ross Sea in Antarctica. The project, which began in the summer of 2010 and ended in May 2011, consisted of several components: (1) A multidisciplinary teacher-education team that included educators, scientists, Web 2.0 technology experts and storytellers, and a photographer/writer blogging team; (2) Twenty-five middle-school and high-school earth science teachers, mostly from New Jersey but also New York and California; (3) Weeklong summer teacher institute at Liberty Science Center (LSC) where teachers and scientists met, and teachers learned about questions to be investigated and technologies to be used during the mission, and how to do the science to be conducted in Antarctica; (4) COSEE NOW interactive community website where teachers, LSC staff and other COSEE NOW members shared lesson plans or activities and discussed issues related to implementing the mission-based science in their classrooms; (5) Technological support and consultations for teachers, plus online practice sessions on the use of Web 2.0 technologies (webinars, blogs, digital storytelling, etc.); (6)Daily shipboard blog from the Ross Sea created by Chris Linder and Hugh Powell (a professional photographer/writer team) and posted on the COSEE NOW website to keep teachers and students up-to-date in real-time on science experiments, discoveries and frustrations, as well as shipboard life; (7) Live webinar calls from the Ross Sea, facilitated by Rutgers and LSC staff, where students posed questions and interacted directly with shipboard researchers and staff; and (8) A follow-up gathering of teachers and scientists near the end of the school year to debrief on the mission and preliminary findings. What resulted from this project was not only the professional development of teachers, which extended into the classroom and to students, but also the development of a relationship that teachers and students felt they had with the scientists and the science. Via personal and virtual interactions, teachers and students connected to scientists personally, while engaged in the science process in the classroom and in the field.
Researchers have now acquired so much information about how the brain learns that a new academic discipline has been born, called “educational neuroscience” or “mind, brain, and education science.” This field explores how research findings from neuroscience, education, and psychology can inform our understandings about teaching and learning, and whether they have implications for educational practice. This interdisciplinary approach ensures that recommendations for applying these findings to instructional practices have a foundation in solid scientific research. It also ensures that teachers
In this interview, author and professor R. Keith Sawyer describes the importance of and interconnections among creativity, collaboration, and the science of learning. He explains that the older paradigm of schooling from 50 years ago where rote learning was predominant is no longer relevant in a knowledge-based society. We now have to prepare students for jobs that require adaptability, flexibility, and creativity. He endorses an approach to education that fosters a deeper conceptual understanding, especially through collaborative creativity. He maintains that true innovation usually comes
Recent advances in neuroscience are highlighting connections between emotion, social functioning, and decision making that have the potential to revolutionize our understanding of the role of affect in education. In particular, the neurobiological evidence suggests that the aspects of cognition that we recruit most heavily in schools, namely learning, attention, memory, decision making, and social functioning, are both profoundly affected by and subsumed within the processes of emotion; we call these aspects emotional thought. Moreover, the evidence from brain-damaged patients suggests the
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Mary Helen Immordino-YangAntonio Damasio
This report highlights advances in neuroscience with potential implications for education and lifelong learning. The report authors, including neuroscientists, cognitive psychologists and education specialists, agree that if applied properly, the impacts of neuroscience could be highly beneficial in schools and beyond. The report argues that our growing understanding of how we learn should play a much greater role in education policy and should also feature in teacher training. The report also discusses the challenges and limitations of applying neuroscience in the classroom and in learning
In this article, I review recent findings in cognitive neuroscience in learning, particularly in the learning of mathematics and of reading. I argue that while cognitive neuroscience is in its infancy as a field, theories of learning will need to incorporate and account for this growing body of empirical data.
For over 60 years annual Science Fairs and Engineering competitions have been held in schools and communities throughout the country, engaging large numbers of middle school students and culminating in national and international events. Science fairs are at the intersection of formal learning in school and informal science learning in other settings including science centers, after-school programs, and clubs. However, in spite of their wide implementation and long history, there are few empirical studies that have examined the relationship between student participation in these fairs and their learning and interest in science. Additionally, there have been no studies to understand the real cost of these programs relative to the student benefits. This educational research project will fill that gap in understanding. It will systematically document and describe science fair models; measure their impact on learning; and provide evidence about the costs of various models and related benefits. The findings from this study will inform a wide range of stakeholders (including teachers, science fair leaders, volunteers, parents, and businesses) about these models and how they impact students' mastery of science and engineering practices. This four-year study in all regions of the country will be conducted in two phases: Phase 1 will be a survey of 3800 middle school science teachers will define the characteristics of science fair models; Phase 2 will use those understandings to conduct case studies in 20 schools. Deliverables include handbooks for teachers and the science fair community, articles in journals summarizing findings, the Science and Engineering Practice and Interest Inventory, and a suite of data collection instruments for scoring rubrics to describe science fairs and measure their impact. Research questions will include: (1) What are the basic models of middle school science fairs? (2) To what extent does participation in a particular model enhance students' mastery of science and engineering practices and/or their interest in science? (3) What student-teacher and school-level factors contribute to or inhibit students' mastery? (4) What resources, human and financial, are required to implement an effective middle school science fair? and (5) What are the most cost-effective aspects of the science fair experience, and how can they be applied or adapted by science fair leaders and teachers to strengthen students' mastery of science and engineering practices? Findings from this study will have the potential to improve current practices in the design and implementation of science fairs and their impact on student learning; they will be widely disseminated to the various stakeholders through publications, conference presentations, and educational association channels.