Bridging Earth and Mars (BEAM): Engineering Robots to Explore the Red Planet engages the general public and K-8 students in exhibits and programs designed to foster awareness of robotic technology, computer programming, and the challenges and opportunities inherent in NASA missions and S-STEM careers. The Saint Louis Science Center (SLSC) of St. Louis, Missouri is the lead institution and project site; partners include Washington University in St. Louis, Saint Louis University, the St. Louis regional FIRST Robotics organization, and the Challenger Learning Center-St. Louis. Project goals are to: 1) inform, engage, and inspire the public to appreciate NASA’s Mission by sharing findings and information about NASA’s missions to Mars; 2) ignite interest in S-STEM topics and careers for diverse K-8 students; and, 3) encourage students in grades 6-8 to sustain participation in educational experiences along the S-STEM careers pipeline. The SLSC will design and build a Martian surface and panorama where two rovers can be remotely controlled. Visitors in the McDonnell Planetarium will use controllers to program rover exploration of the Martian landscape in real-time. Visitors in SLSC’s Cyberville gallery, located one-quarter mile away across a highway-spanning enclosed bridge, will program the second rover with simulated time lag and view its movements via a two-way camera system. SLSC will organize and host a series of Innovation Workshops for K-8 students, each featuring teamwork-building engineering challenges from current and updated NASA-based science curricula. Participants will be recruited from SLSC community partners, which include community centers and faith-based programs for underserved families.
The Aviation Adventure Center with Traveling Flight Science Lab is a three-year project developed by the Hiller Aviation Museum in San Carlos, California with the intention to deliver immersive STEM programming focused on aeronautics, physical science, weather and general aviation subjects for a general museum audience and K-12 school groups. The lead institution is the Hiller Aviation Museum with additional museum partners including Evergreen Aviation Museum in McMinnville, Oregon, Pueblo Weisbrod Aircraft Museum, in Pueblo, Colorado, Frontiers of Flight Museum in Dallas, Texas, and New England Air Museum in Windsor Locks, Connecticut. The two goals of the project are 1) to create an in-house laboratory-style program area, called Aviation Adventure Center, permanently located within the exhibition gallery of the Hiller Aviation Museum and 2) to create a traveling flight simulation program/exhibit, called Traveling Flight Science Lab, that toured four aviation museums, listed above. During three years of the project a total of 48,530 participants were served in 4,476 programs. The project concluded in June, 2012. The Aviation Adventure Center continues as a centerpiece of Hiller Aviation Museum programming to this day.
This is a summary of results and evaluations of the first citizen science project awarded by the National Science Foundation to the Cornell Lab of Ornithology in 1992 (before the term "citizen science" was used to define public participation in scientific research and before the Internet or even computers were in widespread use). The report lists several publications and evaluation reports, none of which are available electronically as of April, 2014. For more information about these reports and the data they contain please contact Rick Bonney (RickBonney@cornell.edu).
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Cornell Lab of OrnithologyRick Bonney
The John G. Shedd Aquarium’s Department of Learning Planning & Evaluation synthesizes learning research, develops evaluation plans with Learning Group staff, and assists with data analysis and interpretation for education programs. The Research Associate’s primary responsibility is reviewing literature, both research-based and practitioner-based, and synthesizing these findings into comprehensive research narratives. These narratives are used by staff members in the Learning Group to help them determine their suite of experiences and instructional strategies. Depending on the topic of the
This paper advocates for place-based education to guide research and design for mobile computers used in outdoor informal environments (e.g., backyards, nature centers and parks). By bringing together research on place-based education with research on location awareness, we developed three design guidelines to support learners to develop robust science-related understandings within local communities. The three empirically- derived design guidelines are: (1) Facilitate participation in disciplinary conversations and practices within personally-relevant places, (2) Amplifying observations to see
Web 2.0 technologies have introduced increasingly participatory practices to creating content, and museums are becoming interested in the potentials of “Museum 2.0” for reaching and engaging with new audiences. As technological advances are opening up the ways in which museums share information about the objects in their collections, the means by which museums create, handle, process, and transmit knowledge has become more transparent. For this to be done effectively, however, some underlying contradictions must be resolved between museum practices, which privilege the account of the “expert,”
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Ramesh SrinivasanRobin BoastJonathan FurnerKatherine Becvar
This review takes a critical position with regards to Treagust and Duit’s article, Conceptual Change: A discussion of theoretical methodological and practical challenges for science education. It is proposed that conceptual change research in science education might benefit from borrowing concepts currently being developed in the sociology of emotions. It is further suggested that the study of social interaction within evolving emotional cultures is the most promising avenue for developing and extending theories about conceptual change.
This paper suggests new strategies for introducing students to robotics technologies and concepts, and argues for the importance of providing multiple entry points into robotics. In particular, the paper describes four strategies that have been successful in engaging a broad range of learners: (1) focusing on themes, not just challenges; (2) combining art and engineering; (3) encouraging storytelling; (4) organizing exhibitions, rather than competitions. The paper describes a new technology, called the PicoCricket, that supports these strategies by enabling young people to design and program
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Natalie RuskMitchel ResnickRobbie BergMargaret Pezalla-Granlund
In responding to the research on conceptual change, this article attempts to make two points. First, scientific concepts are not possessed by individuals; rather, they are part of a culture’s resources, which individuals learn to use for their own or for group purposes. Second, particular concepts are most effectively mastered when the learner is deeply engaged in solving a problem for which they function as effective semiotic tools in achieving a solution. On these grounds, it is argued that the mastering of scientific concepts is best achieved through learning to use them in motivated
Argumentation has become an increasingly recognized focus for science instruction---as a learning process, as an outcome associated with the appropriation of scientific discourse, and as a window onto the epistemic work of science. Only a small set of theoretical conceptualizations of argumentation have been deployed and investigated in science education, however, while a plethora of conceptualizations have been developed in the interdisciplinary fields associated with science studies and the learning sciences. This paper attempts to review a range of such theoretical conceptualizations of
Challenged by a National Science Foundation-funded conference, 2020 Vision: The Next Generation of STEM Learning Research, in which participants were asked to recognize science, technology, engineering, and mathematics (STEM) learning as lifelong, life-wide, and life-deep, we draw upon 20 years of research across the lifespan to propose a new way of thinking about and investigating the topic. We propose Fullness of Life (or Total Life) as the minimal unit of analysis that allows people generally and researchers specifically to make sense of cognition. This move reverses traditional
Although there has been considerable focus on the underrepresentation of minorities in science, technology, engineering, and mathematics (STEM) disciplines and the need for science instruction that fosters diversity, much of the associated effort has focused on the goal of diversity and tended to assume that science and science learning are acultural. We describe a conceptual framework employed in our work with both urban and rural Native American communities that focuses on culturally based epistemological orientations and their relation to the cultural practices associated with science