As teachers respond to the demands of educational reform and strive to meet increasing pressures of educational benchmarks and standards, there is less and less time to utilize innovative teaching techniques. Education reform expectations, coupled with increasing class size and shrinking budgets has significantly impacted the way that science education is delivered in schools. 4-H Wildlife Stewards, a Master Science Educator's Program was developed in response to these emerging concerns in science education. The program is based on the premise that trained volunteer Master Science Educators
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TEAM MEMBERS:
Mary ArnoldMichael DaltonMaggie LivesayRobin Galloway
SciGirls is a national outreach program of DragonflyTV supported by a grant from the National Science Foundation's Program for Gender Equity. SciGirls empowers PBS outreach professionals and science museum educators, often partnering with local youth organizations, educators and parents, to deliver hands-on science encouragement and career guidance to girls in their communities. SciGirls is based on existing standards-based DragonflyTV outreach resources, which teach scientific inquiry.
This report summarizes a summative evaluation of Amazing Feats of Aging, an exhibition developed by staff at the Oregon Museum of Science and Industry (OMSI) in Portland, Oregon. Patricia McNamara, an independent evaluator, designed this study to document the exhibition's impact on visitors at two locations: its permanent installation at OMSI itself and at the installation of the exhibit's traveling version at the Lafayette Museum of Natural History (LMNH) in Lafayette, Louisiana. Data collection strategies included visitor interviews, self-administered questionnaires and unobtrusive
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TEAM MEMBERS:
Patricia McNamaraOregon Museum of Science and Industry
The Maryland Science Center has received a SEPA grant to develop an exhibition, intern program and web site focusing on cell biology and stem cell research. The working title of the exhibition is Cellular Universe. The exhibit is intended to serve the following audiences: Families with children age nine and older; School groups (grades four and up); Adults; 9th grade underserved high school students in three local schools and/or community centers. Topics the exhibit will treat include: Structure and function of cells; Stem cells and their potential, the controversy surrounding stem cell
Each year, more than 200 volunteers donate over 7,000 hours of their time, skills, and enthusiasm to reach Jug Bay Wetlands Sanctuary's goals in environmental education, scientific research, and the protection of the vulnerable wetland ecosystem. This is the equivalent of a $100,000 donation. These volunteers have a variety of backgrounds---teachers, librarians, construction workers, chemists, college and high school students, and yes, some are even professional wetland ecologists! What they have in common is an interest in nature, pleasure in being outdoors, and a desire to explore the ecology of natural habitats such as wetlands and forests. At the Sanctuary, they collect water samples . . . clear trails . . . weigh turtles . . . guide visitors on nature walks . . . draw maps . . . lead canoe trips . . . make posters . . . seine for fish . . . host the Visitor Center on weekends . . . and so much more!
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TEAM MEMBERS:
Jug Bay Wetlands SanctuaryFriends of Jug BayChesapeake Bay National Estuarine Research Reserve SystemLindsay Hollister
This Small Business Innovation Research (SBIR) Phase I project will demonstrate the feasibility of engaging children ages 8 to 13 in the wonders of science and the application of scientific principles through the transmedia SCIENTASTIC! project. The study will also demonstrate that the television series will help students answer questions and solve problems for themselves and their community. The American public supports the advancement of scientific knowledge and our investment in scientific research leads the world. However, Americans are falling behind in educating the next generation of scientists. Late elementary school is an ideal time to capture students' attention and engage them in STEM activities. Using rigorous evaluation techniques we will show that SCIENTASTIC! encourages hands-on learning by exploration, questioning and thinking. The innovative television program and integrated companion resources provide scientific role models and demonstrate the scientific process in an entertaining way. The associated web site, Apps, Web 2.0 repository and teaching aids allow students, teachers, and parents to further explore concepts introduced in the show. Preliminary analysis reveals that the SCIENTASTIC! target audience liked the show, would watch the show and learned from the show. Further analysis will demonstrate that the transmedia approach increases viewer interest and learning. The broader impact/commercial potential of this project will play a transformative role in encouraging students to take STEM courses in college, pursue scientific careers, and become a scientifically informed electorate. By developing the story beyond the story, transmedia SCIENTASTIC! has strong commercial value. Dissemination through public television allows for a potential audience of 250 million people. Commercial and noncommercial sponsorships will be sold with associated on-air credits. Additional direct funding will be sought from industries with interests in promoting science and health literacy. A commercial version of the program will be offered to cable networks on a licensing basis, with DVDs, Apps and study guides sold to schools, homeschoolers, and parents. With a broad and commercially viable dissemination, SCIENTASTIC! will show children the joys of science by demonstrating and engaging in hands-on, team- based learning in real-world contexts. This process will improve student retention and will show that SCIENTASTIC! introduces new ways to learn. The SCIENTASTIC! project will evaluate teaching techniques information that will be shared with policy-makers, educational institutions, and teachers to improve education nationwide. By spreading successful methods for engaging children in math and science, SCIENTASTIC! shoiuld have significant societal benefit creating a generation of scientifically educated decision-makers.
Nationally, there is tremendous interest in enhancing participation in science, technology, engineering, and mathematics (STEM). Providing rich opportunities for engagement in science and engineering practices may be key to developing a much larger cadre of young people who grow up interested in and pursue future STEM education and career options. One particularly powerful way to engage children in such exploration and playful experimentation may be through learning experiences that call for tinkering with real objects and tools to make and remake things. Tinkering is an important target for research and educational practice for at least two reasons: (1) tinkering experiences are frequently social, involving children interacting with educators and family members who can support STEM-relevant tinkering in various ways and (2) tinkering is more open-ended than many other kinds of building experiences (e.g., puzzles, making a model airplane), because it is the participants' own unique questions and objectives that guide the activity. Thus, tinkering provides a highly accessible point of entry into early STEM learning for children and families who do not all share the same backgrounds, circumstances, interests, and expertise. This Research-in-Service to Practice project is funded by the Advancing Informal STEM Learning (AISL) program which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. The project will take place in the Tinkering Lab exhibit at Chicago Children's Museum. The research will investigate how reflective interactions between parents and children (ages 6-8) during tinkering activities ultimately impact child engagement in STEM. Design-based research (DBR) is well-suited to the iterative and contextually-rich process of tinkering. Using a DBR approach, researchers and museum facilitators will be trained to prompt variations of simple reflection strategies at different time points between family members as a way to strengthen children's engagement with, and memory of these shared tinkering events. Through progressive refinement, each cycle of testing will lead to new hypotheses that can be tested in the subsequent round of observations. The operationalization of study constructs and their measurement will come organically from families' activities in the Tinkering Lab and will be developed in consultation with members of the advisory board. Data collection strategies will include observation and interviews; a series of coding schemes will be used to make sense of the data. The research will result in theoretical and practical understanding of ways to enhance STEM engagement and learning by young children and their families through tinkering. A diverse group of at least 350 children and their families will be involved. The project will provide much needed empirical results on how to promote STEM engagement and learning in informal science education settings. It will yield useful information and resources for informal science learning practitioners, parents, and other educators who look to advance STEM learning opportunities for children. This research is being conducted through a partnership between researchers at Loyola University of Chicago and Northwestern University and museum staff and educators at the Chicago Children's Museum.
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative resources for use in a variety of settings. This research project leverages ongoing longitudinal research to investigate whether, and if so how, youth from ages 10 to 15 in a diverse, under-resourced urban community become interested and engaged in STEM. The project addresses a global issue; fewer youth choose to major in scientific fields or take science coursework at high school or university levels. These declining numbers result in fewer STEM professionals and fewer scientifically literate citizens who are able to function successfully in an increasingly scientific and technological society. These declines are observed for youth as a whole, but are most pronounced for girls and particular non-white ethnic minorities. Data collected from youth in this community of study, including non-white ethnic minorities, mirrors this decline. NSF funding will support a five-year systematic and systemic process in which project researchers work collaboratively with existing informal and formal educational partners (e.g., museums, libraries, afterschool providers, schools) to develop sets of customized, connected, and coordinated learning interventions, in and out of school, for youth with different backgrounds, needs, and interests, all with the goal of averting or dampening this decline of STEM interest and participation during early adolescence. In addition to new research and community STEM networks, this project will result in a Community Toolkit that includes research instruments and documentation of network-building strategies for use by other researchers and practitioners nationally and internationally. This mixed methods exploratory study has two distinct but interrelated populations - youth and educators from across informal and formal institutions. To develop a clearer understanding of the factors that influence youths' STEM interest development over time, particularly among three youth STEM Interest Profiles identified in a secondary analysis (1-Dislike Math, 2-Like all STEM, 3-Dislike all STEM), the design combines surveys with in-depth interviews and observations. To study educators and institutions, researchers will combine interviews, focus groups, and observations to better understand factors that influence community-wide, data-driven approaches to supporting youth interest development. Research will be conducted in three phases with the goal of community-level change in youth STEM interest and participation. In Phase 1 (Years 1 & 2) four educational partners will develop interventions for a 6th and 7th grade youth cohort that will be iteratively refined through a design-based approach. Educational partners and researchers will meet to review and discuss interest and participation data and use these data to select content, as well as plan activities and strategies within their programs (using a simplified form of conjecture mapping). By Phase 2 (Years 3 & 4) four additional partners will be included, more closely modeling the complex system of the community. With support from researchers support and existing partners, new educational partners will similarly review and discuss data, using these to select content, as well as plan activities consistent with program goals and strategies. Additional interventions will be implemented by the new partners and further assessed and refined with a new 6th and 7th grade cohort, along with the existing interventions of the first four partners. In Phase 3 (Year 5) data will be collected on pre-post community-level changes in STEM interest and participation and the perceived effectiveness of this approach for youth. These data will inform future studies.
The Cyberlearning and Future Learning Technologies Program funds efforts that support envisioning the future of learning technologies and advance what we know about how people learn in technology-rich environments. Development and Implementation (DIP) Projects build on proof-of-concept work that shows the possibilities of the proposed new type of learning technology, and PI teams build and refine a minimally-viable example of their proposed innovation that allows them to understand how such technology should be designed and used in the future and that allows them to answer questions about how people learn, how to foster or assess learning, and/or how to design for learning. This project is building and studying a new type of online learning community. The WeatherBlur community allows kids, teachers, scientists, fishermen/fisherwomen, and community members to learn and do science together related to the local impacts of weather and climate on their coastal communities. Members of the community propose investigations, collect and share data, and learn together. WeatherBlur is designed to be a new form of knowledge-building community, the Non-Hierarchical Online Learning Community. Unlike other citizen science efforts, there is an emphasis on having all members of the community able to propose and carry out investigations (and not just help collect data for investigations designed by expert scientists or teachers). Prior research has demonstrated important structural differences in WeatherBlur from other citizen science learning communities. The project will use social network analysis and discourse analysis to measure learning processes, and Personal Meaning Mapping and embedded assessments of science epistemology and graph interpretation skills to examine outcomes. The measures will be used to explore knowledge-building processes and the scaffolds required to support them, the negotiation of explanations and investigations across roles, and the epistemic features that drive this negotiation process. The work will be conducted using an iterative design-based research process in which the prior functioning WeatherBlur site will be enhanced with new automated prompt and notification systems that support the non-hierarchical nature of the community, as well as tools to embed assessment prompts that will gauge participants' data interpretation skills and epistemic beliefs. Exponential random graph modeling will be used to analyze the social network analysis data and test hypotheses about the relationship between social structures and outcomes.
The Next Generation Science Standards (NGSS) identify an ambitious progression for learning energy, beginning in elementary school. To help the nation's teachers address this challenge, this project will develop and investigate the opportunities and limitations of Focus on Energy, a professional development (PD) system for elementary teachers (grades 3-5). The PD will contain: resources that will help teachers to interpret, evaluate and cultivate students' ideas about energy; classroom activities to help them to identify, track and represent energy forms and flows; and supports to help them in engaging students in these activities. Teachers will receive the science and pedagogical content knowledge they need to teach about energy in a crosscutting way across all their science curricula; students will be intellectually engaged in the practice of developing, testing, and revising a model of energy they can use to describe phenomena both in school and in their everyday lives; and formative assessment will guide the moment-by-moment advancement of students' ideas about energy. This project will develop and test a scalable model of PD that will enhance the ability of in-service early elementary teachers to help students learn energy concepts by coordinating formative assessment, face-to-face and web-based PD activities. Researchers will develop and iteratively refine tools to assess both teacher and student energy reasoning strategies. The goals of the project include (1) teachers' increased facility with, and disciplined application of, representations and energy reasoning to make sense of everyday phenomena in terms of energy; (2) teachers' increased ability to interpret student representations and ideas about energy to make instructional decisions; and (3) students' improved use of representations and energy reasoning to develop and refine models that describe energy forms and flows associated with everyday phenomena. The web-based product will contain: a set of formative assessments to help teachers to interpret student ideas about energy based on the Facets model; a series of classroom tested activities to introduce the Energy Tracking Lens (method to explore energy concept using multiple representations); and videos of classroom exemplars as well as scientists thinking out loud while using the Energy Tracking Lens. The project will refine the existing PD and build a system that supports online implementation by constructing a facilitator's guide so that the online community can run with one facilitator.
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TEAM MEMBERS:
Sara LacyRoger TobinNathaniel BrownStamatis VokosRachel ScherrKara GrayLane SeeleyAmy Robertson
Field trips to science museums can provide students with educational experiences, particularly when museum programs emphasize scientific inquiry skill building over content knowledge acquisition. We describe the creation and study of 2 programs designed to significantly enhance students' inquiry skills at any interactive science museum exhibit without the need for advanced preparation by teachers or chaperones. The programs, called Inquiry Games, utilized educational principles from the learning sciences and from visitor studies of museum field trips. A randomized experimental design compared