My Sky is a joint project between Boston Children’s Museum (BCM) and the Smithsonian Astrophysical Observatory (SAO). This three-year project was supported by NASA’s NRA/ROSES 2011 (NNX12AB91G) program, and resulted in the creation of My Sky, a 1,500 sq. ft. traveling astronomy exhibit designed for adults and children, ages 5 – 10. My Sky emphasizes authentic experiences that encourage the development of skills and content foundational to later appreciation and understanding of astronomical science. My Sky includes interactive explorations of objects and phenomena visible in the sky, encouraging families to “look up” not only when they visit the exhibit, but as a practice they might adopt in their everyday lives. This is all punctuated by real NASA data and assets, including a 5’ diameter model Moon created using the latest Lunar Reconnaissance Orbiter measurements; and high-resolution images from NASA’s Solar Dynamics Observatory satellite. This project also developed a series of public programs, museum staff training programs, and family workshops, all utilizing NASA resources and existing curriculum.
In late 2012, Providence Children’s Museum began a major three-year research project in collaboration with The Causality and Mind Lab at Brown University, funded by a grant from the National Science Foundation (1223777). Researchers at Brown examined how children develop scientific thinking skills and understand their own learning processes. The Museum examined what caregivers and informal educators understand about learning through play in its exhibits and how to support children’s metacognition – the ability to notice and reflect on their own thinking – and adults’ awareness and appreciation of kids’ thinking and learning through play. Drawing from fields like developmental psychology, informal education and museum visitor studies, the Museum’s exhibits team looked for indicators of children’s learning through play and interviewed parents and caregivers about what they noticed children doing in the exhibits, asking them to reflect on their children’s thinking. Based on the findings, the research team developed and tested new tools and activities to encourage caregivers to notice and appreciate the learning that takes place through play.
In the editorial of this issue of JCOM, we underline how children are on one hand one of the main target group for science communication, and on the other hand a largely excluded group in the shift from a linear diffusion model to a dialogic model of science communication. In this series of comments, stimulated by the EU - FP7-Science in society project `SiS-Catalyst - 2013 children as change agents for science in society' (a four year programme aimed at crossing the science in society and the social inclusion agendas), we would like to explore methods and approaches that can ensure that, in
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Matteo MerzagoraTricia Alegra Jenkins
Researchers at the American Association of Variable Star Observers, the Living Laboratory at the Boston Museum of Science, and the Adler Planetarium are studying stereoscopic (three-dimensional or 3D) visualizations so that this emerging viewing technology has an empirical basis upon which educators can build more effective informal learning experiences that promote learning and interest in science by the public. The project's research questions are: How do viewers perceive 3D visualizations compared to 2D visualizations? What do viewers learn about highly spatial scientific concepts embedded in 3D compared to 2D visualizations? How are viewers\' perceptions and learning associated with individual characteristics such as age, gender, and spatial cognition ability? Project personnel are conducting randomized, experimental mixed-methods research studies on 400 children and 1,000 adults in museum settings to compare their cognitive processing and learning after viewing two-dimensional and three-dimensional static and dynamic images of astronomical objects such as colliding galaxies. An independent evaluator is (1) collecting data on museum workers' and visitors' perceived value of 3D viewing technology within museums and planetariums and (2) establishing a preliminary collection of best practices for using 3D viewing technology based on input from museum staff and visitors, and technology creators. Spatial thinking is important for learning many domains of science. The findings produced by the Two Eyes, 3D project will researchers' understanding about the advantages and disadvantages of using stereoscopic technology to promote learning of highly spatial science concepts. The findings will help educators teach science in stereoscopic ways that mitigate problems associated with using traditional 2D materials for teaching spatial concepts and processes in a variety of educational settings and science content areas, including astronomy.
In partnership with the University of Pennsylvania's Graduate School of Education, The Franklin Institute Science Museum will develop, test, and pilot an exportable and replicable cyberlearning exhibit using two cutting edge technologies: Augmented Reality (AR) and Virtual Reality (VR). The exhibit's conceptualization is anchored in the learning research vision of the NSF-funded workshop Cyberinfrastructure for Education and Learning for the Future (Computing Research Association, 2005). The incorporation of VR and AR technologies into the Franklin Institute's electricity and Earth science exhibits is an innovation of traditional approaches to hands-on learning and will improve the quality of the learning experience for the primary audience of families with children and elementary school groups. The project has implications for future exhibit development and more broadly, will provide new research on learning on how to incorporate cyberlearning efforts into traditional exhibits. Fifteen participating exhibit developers across the ISE field will assist in the evaluation of the new exhibit; receive training on the design and development of VR and AR exhibits for their institutions; and receive full access to the exhibit's new software for implementation at their informal learning sites. The technology applications will be developed by Carnegie Mellon University's Entertainment Technology Center--leaders in the field in Virtual Reality design and development. Front-end and formative evaluation will be overseen internally by the Franklin Institute. The Institute for Learning Innovation will conduct the summative evaluation. Research will be conducted by the University of Pennsylvania's Graduate School of Education on the effects of AR and VR technologies on exhibit learning.
Magnolia Consulting, LLC conducted a formative and summative evaluation to examine public perceptions of the utility and quality of two labs/exhibits within the North Carolina Museum of Natural Sciences Natural World Investigate Lab, Biofuels and Science of Scent. Appendix includes survey.
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North Carolina State Museum of Natural ScienceMary Styers
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 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.
This article describes how two inquiry games promoted student science skills in a museum setting while minimizing demands on teachers, fostering collaboration, and incorporating chaperones. Students who played these games engaged in more scientific inquiry behaviors than did students in control groups.
Informal Community Science Investigators (iCSI) creates a network of four geographically diverse informal science institutions working together on strategies to engage youth ages 10-13 through location based augmented reality (AR) games played on smartphones. These high-interest, kid-friendly games will be used by families visiting the institutions and by youth who enroll in more intensive summer camp programs. Using AR games, participants will engage in playful but scientifically-grounded investigations drawing on each institution's research, exhibits, and natural spaces. For example, a botanical garden might engage young visitors through AR games with themes related to native and invasive species, while a zoo might create a game experience focusing on illegal wildlife trade. Participants in the iCSI summer camp program will have more intensive experiences, including work with the host institution's scientists, opportunities to develop original augmented reality games, and experiences with game-related service learning and citizen science programs. For both target groups (families and campers), the location specific games build understanding of both the institution's mission and the broader realm of scientific research and application. The project will test the notion of participants as "learner hero," the link between game play and the individual's development of competency, autonomy and the relationship to real world experience, in this case through community action on the subject of the game developed. To that end, participants will be encouraged to extend their involvement through related investigations on site and participation in community activities and projects that can be done at home. Social media tools such as Facebook and web sites managed by the host institutions will provide recognition for this extended engagement, helping participants maintain ties to the program. Additionally, program resources provide assistance to adult family members in nurturing and sustaining youth interest in STEM activities and careers. A major effort of the project will be development of a new software infrastructure called TaleBlazer for the augmented reality game that will enable teachers and students to develop their own game that incorporates real data collection and scientific model building. The new platform will enhance the game play platform MITAR developed with NSF funding.
The Decapoda - shrimp, lobsters, and crabs - are an economically important, diverse group of animals whose geologic history extends back 400 million years. Living representatives, numbering over 15,000 species, are global in distribution and nearly ubiquitous in oceanic and non-oceanic environments. They exert a major impact on ecosystems; understanding the dynamics of their fossil record will illuminate their historical impact on ecosystems. We will test the hypothesis that decapods are arrayed in a series of discrete evolutionary faunas; remarkably, the vast array of living and fossil decapods in diverse interrelated groups have exploited four basic body plans repeatedly. Other hypotheses to be tested are that the Decapoda have repeatedly adopted a limited number of baupläne, or generalized architectures, throughout their history; that they have experienced explosive evolutionary radiations followed by periods of no determinable change; and that they are generally resistant to mass extinction events. These hypotheses will be tested using a unique dataset compiled and assessed by the Principle Investigators: a compilation of all fossil decapod species, arrayed in a classification scheme including fossil and living taxa, with geologic and geographic ranges of all species, including a phylogeny (i.e. "family tree") for many sub-groups within the Decapoda. The dataset will be expanded to include ecological data for each taxon and will be entered into the Paleobiology Database, an NSF-supported vehicle for analyzing the fossil record. Employing its methodology, patterns of diversity and macroevolution of the decapods will be generated at levels ranging from the entire Order to species level. This will result in a comprehensive analysis of macroevolutionary patterns of this major group for the first time. Available paleoecological data derived from field studies and published records will be used to determine the effects of various environmental factors such as seafloor conditions, reef development, water depth, and temperature on morphology, extinction survivorship, and diversity. Because decapods have a remarkable range of morphological variation preservable in the fossil record, the diversity of the groups of decapods can be assessed in relation to their morphological characteristics. Defining the history of taxa with specialized morphology will permit recognition of body plans that have been exploited by different decapod groups throughout the history of the clade.
Intellectual merit. This study will provide the most comprehensive analysis of macroevolution of the Decapoda yet conducted, all based upon a unique dataset that is internally consistent by virtue of its having been developed entirely by the investigators. It will document the significance of employing a high resolution, species-level database for interpretation of diversity. The hypotheses and conclusions derived here will provide a model and the foundation for future work on Decapoda, Arthropoda, and macroevolution of well-constrained groups. It will provide a test for the efficacy of PBDB data versus a constrained dataset assessed by specialist systematists.
Broader impacts. The work will introduce undergraduate students at Kent State at Stark, an undergraduate campus, and Kent State at Kent, to research that involves paleoecological, paleogeographical, and functional morphological elements which, in turn, will be communicated to other students. Because decapods are known to virtually everyone, they form an excellent group to use to inform the public about ancient patterns of diversity and the relationship between the morphology of organisms, variations in their environmental requirements, and their adaptability to different physical conditions. This will be conveyed in a professionally constructed display which has the potential to be exhibited in museums and universities around the country. Small kits designed for use in elementary and middle schools will be available to allow students to make their own observations about the adaptations of decapods to their environment and its effect on diversity. Published papers and presentations on results of research at meetings will be prepared throughout the course of the research. Because the study of modern biodiversity is a concern of the general public, presentations to broader audiences as well as geology classes will provide a broad historical context for understanding modern patterns of diversity. Data entered into Paleobiology Database and Ohio Data Resource Commons will be openly available to other researchers and the general public. Combined, the databases will assure archival storage and public access, following a proprietary period.
The Dynamic Earth: You Have To See it To Believe It is a public exhibition and suite of programming designed to educate and excite K-8 students, teachers, and families about weather and climate science, plate tectonics, erosion, and stream formation. The Dynamic Earth program draws attention to the importance of large-scale earth processes and the human impacts on these processes, utilizing real artifacts, hands-on models, and NASA earth imagery and data. The program includes the exhibition, student workshops, family workshops, annual professional development opportunities for classroom teachers, innovative theater shows, lectures for adults by visiting scientists, and interpretive activities. The Montshire Museum of Science has partnered with Chabot Space and Science Center (CA) and the US Army Corps of Engineers Cold Regions Research and Engineering Laboratory (NH) on various components. The project has broadened our internal capacity for providing quality earth science programming by greatly expanding our program titles and allowing us to create hands-on materials for use by our educators and to loan to schools in our Partnership Initiative. Programming developed during the grant period continues to reach thousands of students and teachers each year, both on-site and as part of our rural outreach efforts.