While we should celebrate our success at evolving many vital aspects of the human-technology interactive experience, we question the scope of this progress. Step back with us for a moment. What really matters? Everyday life spans a wide range of emotions and experiences -- from improving productivity and efficiency to promoting wonderment and daydreaming. But our research and designs do not reflect this important life balance. The research we undertake and the applications we build employ technology primarily for improving tasks and solving problems. Our claim is that our successful future
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TEAM MEMBERS:
Eric PaulosTom JenkinsAugust JokiParul Vora
This thesis adds to the empirical research foundation of informal science education through an investigation of a museum-based astronomy internship for high school students, in the domains of attitudes toward science, knowledge of science, and participatory science learning. Results are presented as three studies, all using a qualitative methodology and including the methods of semi-structured interview, reflective journal, direct observation, audio recording, and artifact collection.
This report presents the findings of a qualitative study that asked 38 secondary science teachers, ‘How can natural history museums effectively support science teaching and learning?’ A partnership of four natural history museums across England, teachers from their local areas and a university education department were involved. The museums work in partnership to support school science at 11–18. In-depth focus groups held at the museums and questionnaires were used.
From March 26-28, 2014, the Coalition for Science After School (CSAS) hosted its final summit, Passing the Torch: Advancing Opportunity for Quality Science Learning. The Summit was intended to: (1) celebrate a decade of progress in strengthening and expanding STEM learning opportunities in out-of-school time; (2) call attention to critical issues in ensuring that all young people have opportunities for quality STEM experiences in their local communities; and (3) stimulate ideas, strategies, partnerships and commitments to continue to increase opportunities for quality STEM experiences across
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TEAM MEMBERS:
The Coalition for Science After SchoolLeah Reisman
This report draws together the results from two major pieces of research–an overview of science communication activities in Britain today, and a detailed understanding of public attitudes to science. By combining the information from both studies, this report aims to inform future science communication strategies for both policy and practice. The research reported here sets a baseline for public attitudes to science, engineering and technology. The survey has been designed to be repeated at regular intervals to monitor any changes in these attitudes. By identifying a number of factors, which
In January 2012, New York Hall of Science (NYSCI) hosted Design-Make-Play: Growing the Next Generation of Science Innovators. The two-day conference brought together leaders of schools, community-based programs, research and development organizations, the funding community, universities, government and business. They gathered at NYSCI to assemble evidence supporting the belief that designing, making and playing can create new pathways into science, technology, engineering and math (STEM), particularly among children. A core argument of Design-Make-Play is that informal learning centers like
Recognizing that the Maker movement embodies aspects of science, technology, engineering, and mathematics (STEM) learning that are the hallmarks of effective education — deep engagement with content, critical thinking, problem solving, collaboration, learning to learn, and more — NYSCI, in collaboration with Dale Dougherty and Tom Kalil, approached the National Science Foundation to sponsor a two-day workshop. Over 80 leaders in education, science, technology and the arts came together at NYSCI to consider how the Maker movement can help stimulate innovation in formal and informal education
In October 2005, the National Science Foundation brought members of its nanoscale science and engineering education (NSEE) projects to Arlington, VA for a 2-day workshop to explore the status of on-going efforts and to forge collaborations at the national level that would facilitate future efforts. NSF currently funds NSEE projects through the Division of Elementary, Secondary, and Informal Education (ESIE), the Directorate for Engineering as part of the Nanoscale Science and Engineering Centers (NSEC), National Nanotechnology Infrastructure Network (NNIN), the Network for Computational
NSF's Cyberinfrastructure Vision for 21st Century Discovery is presented in a set of interrelated chapters that describe the various challenges and opportunities in the complementary areas that make up cyberinfrastructure: computing systems, data, information resources, networking, digitally enabled-sensors, instruments, virtual organizations, and observatories, along with an interoperable suite of software services and tools. This technology is complemented by the interdisciplinary teams of professionals that are responsible for its development, deployment and its use in transformative
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.
Discovering and understanding the temporal evolution of events hidden in text corpora is a complex yet critical task for knowledge discovery. Although mining event dynamics has been an important research topic leading to many successful algorithms, researchers, research and development managers, intelligence analysts and the general public are still in dire need of effective tools to explore the evolutionary trends and patterns. This exploratory project focuses on developing and validating a novel idea called narrative animation. Narrative animation uses animated visualizations to narrate, explore, and share event dynamics conveyed in temporally evolving text collections. Film art techniques are employed to leverage the animated visualizations in information organization and change detection, with the goals of enhancing analytical power and user engagement. A prototype system called CityStories is being developed to generate narrative animations of events in cities derived from web-based text. If this novel, risky research is successful, it is expected to yield fundamental results in narrative animation that can advance the current paradigm in information visualization and visual analytics by developing novel techniques in using animations for presenting and analyzing dynamic abstract data at a large scale. The pilot system CityStories system is expected provide a novel network platform for education, entertainment, and data analytics. It will engage general users such as students, teachers, journalists, bloggers, and many others in web information visualization and study. Results of this research will be disseminated through publications, the World Wide Web, and collaborations with researchers and analysts. The project web site (http://coitweb.uncc.edu/~jyang13/narrativeanimation/narrativeanimation.htm) will include research outcomes, publications, developed software, videos, and datasets for wide dissemination to public.
The purpose of this paper is to examine the role of laboratory-based science from a perspective that synthesizes developments in (1) science studies, e.g., history, philosophy and sociology of science and (2) the learning sciences, e.g., cognitive science, philosophy of mind, educational psychology, social psychology, computer sciences, linguistics, and (3) educational research focusing on the design of learning environments that promote dynamic assessments. Taken together these three domains have reshaped our thinking about the role inquiry, and in turn the laboratory, has in science