This is a Science Learning+ planning project that will develop a research plan for investigating how applying the principles of embodied cognition to the design of informal learning environments can support young children's (ages 2-6) engagement with, and understanding of, science topics and concepts. While it has been fairly well established that cognition is intertwined with the body's interaction in the physical world, the precise means of applying these ideas to the design of effective learning environments is still emerging. Experimenting with various embodied cognition activities and physical learning configurations to understand what conditions are optimal for informal learning environments for early learners is a major objective of this project. During the planning grant period, the project will identity additional practitioner/research collaborations and will develop research plans for a suite of studies to be enacted by multiple teams of informal learning practitioners and cognitive scientists across the US and UK and that will be submitted as a Phase 2 research. The primary activities of this planning period include organizing a series of workshops that bring together informal learning educators and embodied cognition researchers to engage in deep discussion and design experimentation that will inform the development and refinement of research questions, protocols, and measurement tools. These discussions will be informed by observations of young children as they interact with the River of Grass, an exhibit prototype in which principles of embodied cognition are embedded in its design. The planning period will be led by a collaborative team of informal learning practitioners and cognitive scientists from the US and UK. This group will also oversee plans for the development of a new model for informal STEM research in which a constellation of practitioner/research teams across multiple organizations investigates topics of importance to informal learning practice and research that have the potential to result in a robust body of research that informs the design of informal learning spaces.
The National Science Foundation (NSF) awarded funding to the Oregon Museum of Science and Industry (OMSI) and Portland State University (PSU) in Portland, Oregon to support a “Connecting Researchers and Public Audiences” (CRPA) project titled ResearchLink: Spotlight on Solar Technologies. The primary goals of CRPA projects are to communicate to the public about specific NSF research projects. This ResearchLink project promoted public awareness of two NSF-funded projects led by Dr. Carl Wamser at PSU, Integrating Green Roofs and Photovoltaic Arrays for Energy Management and Optimization of
Research in experimental and developmental psychology, cognitive science, and neuroscience, suggests that tool fluency depends on the merging of perceptual and motor aspects of its use, an achievement we call perceptuomotor integration. We investigate the development of perceptuomotor integration and its role in mathematical thinking and learning. Just as expertise in playing a piano relies on the interanimation of finger movements and perceived sounds, we argue that mathematical expertise involves the systematic interpenetration of perceptual and motor aspects of playing mathematical
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Ricardo NemirovskyMolly KeltonBohdan Rhodehamel
This article describes the development of Human +, an exhibition designed to explore the role of technology in daily life explored through the lens of technologies for people with disabilities. Reflecting the design cycle of Participatory Action Design, Human + integrated participation from people with disabilities, both as users and as designers of technology.
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
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 is a handout from a session presented at the 2008 ASTC Conference. Advances in neuroscience are revealing biological pathways underlying emotion, attention, and memory. How can this research be integrated with educational pedagogy to enhance free-choice learning? Join experts from neuroscience, education, and museums to explore practical ways in which new insights about the brain can be applied to creating museum experiences.
This project by teams at the University of Alaska and the Oregon Museum of Science and Industry will engage the public in the topic of the nature and prevalence of permafrost, its scale on the earth and the important role it plays in the global climate. It builds on 50 years of informal education and outreach at the Alaskan Permafrost Tunnel near Fairbanks, AK, which, since the 1960s, has been the Nation's only underground facility for research related to permafrost and climate. The project has four components: (1) a nationally distributed 2,000 square-foot traveling exhibition; (2) exhibit and program enhancements to the learning opportunities at the tunnel; (3) programs, table-top exhibits and oral history research in 27 Native Alaskan villages; and (4) an education research study. Each of these components will be evaluated over the course of the work. By upgrading the displays at the tunnel, and by taking traveling programs to the villages, the work will extend the tunnel experience across Alaska. In the villages the team will collect stories about climate change, along with samples of real ancient ice and permafrost. These stories and materials will be used in the traveling exhibit which is expected to be at three museums per year for eight years. The research component of the initiative will build on the observation to date that the tunnel has provided thousands of visitors with an underground immersive environment where they learn about the science research being conducted and engage with climate-sensitive materials (e.g., permafrost, wedge ice, frozen silt, Pleistocene bones) using all of their senses. It has been conjectured that their learning experiences are enhanced by interacting with real vs. replicated objects. As museums often contain exhibits that are more likely to contain replicated and/or virtual objects and environments, understanding the impact that these different categories of objects have on learning is important. Using both types of materials, the project will investigate differences in their efficacy in informal science learning institutions related to climate change. Real objects are postulated to have the following attributes that stimulate fuller engagement; they are (1) information-rich by virtue of such features as their texture, odor, and dimensionality; (2) at real-life scale; (3) authentic, i.e., original objects; and (4) often unique, i.e., have inherent value. Research questions will explore the potential impacts on learning of these and related features. Methods employed will be observation, video, and interviews of the public with a particular focus on visitor talk with respect to explanations and elaborations about permafrost, tipping points, climate change, and geological time.
This Partnerships for Innovation: Building Innovation Capacity (PFI:BIC) project from the University of New Hampshire focuses on a "living bridge", which exemplifies the future of smart, sustainable, user-centered transportation infrastructure. Bridges deliver such a fundamental service to society that they are often taken for granted. Typically, bridges only stir the public's interest when they must unexpectedly be replaced at great cost, or, worse, fail. The Living Bridge project will create a self-diagnosing, self-reporting "smart bridge" powered by a local renewable energy source, tidal energy, by transforming the landmark Memorial Bridge--a vertical lift bridge over the tidal Piscataqua River, with pedestrian access connecting Portsmouth, New Hampshire to Kittery, Maine--into a living laboratory for researchers, engineers, scientists, and the community at large. The Living Bridge will engage innovators in sensor and renewable energy technology by creating an incubator platform on a working bridge, from which researchers can field test and evaluate the impact and effectiveness of emerging technologies. The Living Bridge will also serve as a community platform to educate citizens about innovations occurring at the site and in the region, and about how incorporating renewable energy into bridge design can lead to a sustainable transportation infrastructure with impact far beyond the region. Sustainable, smart bridges are key elements in developing a successful infrastructure system. To advance the state of smart service systems and clean energy conversion, this project team will design and deploy a structural and environmental monitoring system that provides information for bridge condition assessment, traffic management, and environmental stewardship; advances renewable energy technology application; and excites the general public about bridge innovations. This PFI:BIC project is enabled through partnerships between academic researchers with expertise in structural, mechanical and ocean engineering, sensing technology and social science; small businesses with expertise in instrumentation, data acquisition, tidal energy conversion; and state agencies with bridge design expertise. The Living Bridge technical areas are structural health monitoring, tidal energy conversion with fluid-structure interaction measurements, estuarine environmental monitoring, and outreach communication. Sensors will be used to calibrate a three-dimensional analytical structural finite element model of the bridge. The predicted structural response from this model will assess the measured structural response of the bridge as acceptable or not. Instruments installed on the turbine deployment platform will measure the spatio-temporal structure of the turbulent inflow and modified wake flow downstream of the turbine. Resulting data will include turbine performance and loads for use in fluid-structure interaction models. Deployed environmental sensors will measure estuarine water quality; wildlife deterrent sensors will deter fish from the turbine. Hydrophones and video cameras will be used before and during turbine deployment to monitor environmental changes due to turbine presence. Outreach efforts will make bridge data, history, and information about new systems accessible and understandable to the public and K-12 educators, facilitated by an information kiosk installed at the bridge. Public awareness will be assessed with survey methods used in the N.H. Granite State Poll. The lead institution is the University of New Hampshire (UNH) with its departments of Civil Engineering, Mechanical Engineering, and Sociology, and the Center for Ocean Engineering. Primary industrial partners are a large business, MacArtney Underwater Technology Group, Inc. (Houston, TX) and two small businesses Lite Enterprises, Inc. (Nashua, NH) and Eccosolutions, LLC (New Paltz, NY.) Broader context partners are New Hampshire Department of Transportation, NH Fish & Game Department, NH Port Authority, NH Coastal Program, City of Portsmouth (NH), Sustainable Portsmouth (nonprofit), Maine Department of Transportation; U.S. Coast Guard, Archer/Western (Canton, MA, large business), Parsons-Brinkerhoff (Manchester, NH, large business), UNH Tech Camp, UNH Infrastructure and Climate Network, UNH Leitzel Center for Mathematics, Science and Engineering Education, and Massachusetts Institute of Technology's Changing Places (a joint Architecture and Media Laboratory Consortium, in Cambridge, MA).
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Erin BellTat FuMartin WosnikKenneth BaldwinLawrence Hamilton
This award will engage the public on the issues surrounding the interaction and interdependence of human systems and natural systems. Specifically, it will engage them on human impacts and the health of salmon fisheries in the area of Sitka, Alaska. The public in this area includes the citizens of lower portion of Alaska, K-12 students frequenting the Sitka Sound Science Center on field trips, Alaskan Natives, visiting scientists, and tourists who arrive by cruise ships. The exhibit will be placed at the Sitka Sound Science Center and will include a tank of live salmon fish, a computer game, a 10 minute video, and an artist's rendition of the fishing system and salmon life cycle. The team of scientists from the University of Washington coupled with the exhibit developer, Tenji, Inc., and the outstanding artist, Ray Troll should produce an understandable and marvelously picturesque exhibit for the visitors. This will be augmented by the highly capable staff that has considerable experience in translating science concepts to the public. Media broadcasts will broaden the reach of the exhibit. While the impact of this project is not huge in terms of numbers of people, it is an important endeavor as the people in the Sitka area of Alaska will understand their role in the food system for themselves and for the many other parts of the world. Furthermore, the cruise line visitors will derive an understanding of the fragile environment of the salmon ecosystem.