The goal of this three-year initiative is to expand the implementation of a currently active and proven climate education method delivered by TV weathercasters around the country. The work is a partnership of George Mason University, Yale University, Climate Central (a non-profit climate science research and media production organization), the American Meteorological Society, and NOAA and NASA. This project will include four activities: (1) recruiting 200 TV more weathercasters nationwide (currently just over 100 are participating); (2) providing participating weathercasters with professional development activities and training on use of Climate Matters materials to help them become confident and competent climate educators; (3) developing and distributing to participating weathercasters timely, localized, broadcast-ready graphics and science information, when possible tied to local weather and climatic events, to make it easy for them to educate their viewers about the local relationships between the climate and the weather; and (4) research and evaluation activities to improve the rate of use and effectiveness of Climate Matters materials by weathercasters over time and to study the effect on learning about climate by the public. Learning outcomes by the public will be evaluated using a quasi-experimental method with nationally representative surveys of the public, conducted twice per year over the course of the project. The guiding hypothesis is that there will be a dose-response relationship between the extent of TV weathercaster use of Climate Matters materials in a community (i.e., a media market) and change over time in viewers' understanding of the climate. The development of Climate Matters is based on theories of informal and experiential learning. The scaling up of the initiative applies methods derived from diffusion of innovation and social marketing theories.
This project supports the development of technological fluency and understanding of STEM concepts through the implementation of design collaboratives that use eCrafting Collabs as the medium within which to work with middle and high school students, parents and the community. The researchers from the University of Pennsylvania and the Franklin Institute combine expertise in learning sciences, digital media design, computer science and informal science education to examine how youth at ages 10-16 and families in schools, clubs, museums and community groups learn together how to create e-textile artifacts that incorporate embedded computers, sensors and actuators. The project investigates the feasibility of implementing these collaboratives using eCrafting via three models of participation, individual, structured group and cross-generational community groups. They are designing a portal through which the collaborative can engage in critique and sharing of their designs as part of their efforts to build a model process by which scientific and engineered product design and analysis can be made available to multiple audiences. The project engages participants through middle and high school elective classes and through the workshops conducted by a number of different organizations including the Franklin Institute, Techgirlz, the Hacktory and schools in Philadelphia. Participants can engage in the eCrafting Collabs through individual, collective and community design challenges that are established by the project. Participants learn about e-textile design and about circuitry and programming using either ModKit or the text-based Arduino. The designs are shared through the eCrafting Collab portal and participants are required to provide feedback and critique. Researchers are collecting data on learner identity in relation to STEM and computing, individual and collective participation in design and student understanding of circuitry and programming. The project is an example of a scalable intervention to engage students, families and communities in developing technological flexibility. This research and development project provides a resource that engages students in middle and high schools in technology rich collaborative environments that are alternatives to other sorts of science fairs and robotic competitions. The resources developed during the project will inform how such an informal/formal blend of student engagement might be scaled to expand the experiences of populations of underserved groups, including girls. The study is conducting an examination of the new types of learning activities that are multiplying across the country with a special focus on cross-generational learning.
This multiplatform media and science center project is designed to engage audiences in humanity's deepest questions like the nature of love, reality, time and death in both scientific and humanistic terms. Project deliverables include 5 hour-long radio programs for broadcast on NPR stations, public events/museum exhibits at the Exploratorium in San Francisco, kiosks in venues throughout the city, and a social media engagement campaign. The audience of the project is large and diverse using mass media and the internet. But the project will specifically target young, online, and minority audiences using various strategies. The project is designed to help a diverse audience understand the impact of new scientific developments as well as the basic science, technology, engineering and math needed to be responsible, informed citizens. Innovative elements of the project include the unique format of the radio programs that explore complex topics in an engaging and compelling way, the visitor engagement strategy at the Exploratorium, and the social media strategy that reaches niche audiences who might never listen to the radio broadcasts, but find the podcasts and blogs engaging. The Exploratorium will be opening a new building in 2013 and will include exhibits and programs that are testing grounds for this project. This is a new model that aligns the radio content with exhibitions, social media, and in person events at the Exploratorium, providing a unique holistic approach. The project is designed to inspire people to think and talk about science and want to find out more. The evaluation will measure the impacts on the targeted audiences reached by each of the key delivery methods. Data will be collected using focus groups; intercept interviews with people in public places, and longitudinal panels. The focus will be on 5 targeted audiences (young adults, families with children, non-NPR listeners, underrepresented minorities, and adults without college experience). This comprehensive evaluation will likely contribute important knowledge to the field based on this multiple-platform collaborative model.
This media and research project will develop and study the use of new media, broadcast television, and social networks to introduce Citizen Science to a national audience, and motivate their direct involvement and participation. Project deliverables will include: four nationally-distributed public TV programs hosted by Waleed Abdalati, Director of CIREs at the University of Boulder and former NASA Chief Scientist; online videos for training and outreach of citizen science partners; digital engagement via social media; and a custom-designed application ('2nd screen app') that enables users to obtain additional informational content, share information, and connect with other viewers. The evaluation and research study will build new knowledge on how these deliverables can motivate the public to become citizen science participants. The investigators estimate the four television programs will reach approximately 80% of U.S. television households. In addition, videos and other content will be distributed through channels such as iTunes, Hulu, Netflix, and social media. Target audiences will include the general public, citizen science activists, and professional scientists. Underrepresented groups will be reached through special Google Hangouts, and professional societies such as SACNAS and AGU. The research components of the project will provide evidence on how traditional researchers respond to citizen science, and explore the deliverables' use as recruitment tools for citizen science projects and impacts on viewers' attitudes, behaviors, and skills related to citizen science. Data will be collected from multiple sources, including online surveys, in-person focus groups, and analyses of users' online postings. Retrospective surveys will be administered to explore changes in behavior regarding whether respondents have increased their interaction with professional scientists, or participated in citizen science initiatives. A quasi-experimental study will be conducted to assess the value added by the 2nd screen app.
QUEST Beyond Local is a consortium of six public media providers across the country coming together in a unique collaborative structure to foster widespread STEM literacy for general audiences; support formal and informal education outcomes in the sciences; and revive ailing science and environment journalism in the face of its rapid decline. QUEST Beyond Local is built on the success of the local, cross-editorial QUEST model, in which media making professionals from multiple disciplines--radio, television, web, and especially education--collaborate to distribute high-quality content to general and underserved audiences. Two years ago, KQED (serving Northern California) introduced a capacity-building effort with five other public media stations serving markets across the nation: Seattle (KCTS), Wisconsin (WPT/WPR), Nebraska (NET), Cleveland (ideastream), and North Carolina (UNC-TV). On the heels of this pilot process, QUEST Beyond Local will expand production in all markets and focus its multimedia efforts around the theme "Science of Sustainability" so as to achieve maximum effect on critical STEM outcomes in formal and informal education settings, and to foster science/environment literacy among a wide general audience. QUEST Beyond Local is defined by an organizationally and technologically innovative model of content creation: a newsroom structured according to a hub and spoke model; with common branding, technical, and style guidelines; and with a central coordinating and editorial office liaising between local production teams. Under the guidance of this central office, the collaborative seeks to create content with both local authority and national relevance. Building on existing media impact research, and previous research and evaluation of QUEST, research firm Rockman et al will apply evaluation theory to determine: (1) the structures and strategies to a successful STEM collaborative that contribute to a greater understanding of and engagement in science and environment topics; and (2) determine the interests, priorities, and media consumption habits of local and national STEM audiences. Primary project deliverables include three diverse multimedia packages for general and professional audiences, focusing on three main themes and anchored in STEM disciplines. In total, the three packages will include: 18 television segments; 6 half-hour television programs; 20 radio reports; 18 "web extras" (slide shows, maps, etc.); 12 web-based videos; 144 blog posts; 18 education "explainers"; 5 educator trainings; and a comprehensive distribution and social media campaign. All efforts will be supported by at least 18 science community partners, including zoos, museums, aquariums, research centers, and others. Through these efforts, the collaborative seeks to repair the systemic damage done by years of neglect to science/environment journalism--particularly the marked decline in this type of coverage over the last decade. This decline is perhaps related to the observed disconnect between the public and scientific knowledge, despite a demonstrated public appetite for science content and educators' reported desire for more resources and professional development opportunities focused on STEM topics. At a time when an evolving workforce and economy increasingly demand STEM skills and environmental literacy, QUEST Beyond Local will contribute resources to address these challenges.
This project will bring STEM content knowledge to visitors to Cuyahoga Valley National Park via mobile device applications. Visitors will be able to use their mobile phones to access details about Park features (such as where they are in the park, what they are looking at, and where are related features), supporting just-in-time STEM learning. Cuyahoga Valley National Park receives around 2.5 million visitors every year and experiences multitudes of inquiries. Until this project, visitors were subjected to less than optimum signage for information and background about a given feature that may or may not be of interest to them. In this project, knowledge building information will be selected by the visitors and delivered to them with convenience and speed. The data base supporting this effort will provide the visitor with identification and the history of park features as well as more in depth knowledge building information while they are in the park and after the leave, providing a more holistic experience than is currently available. The investigators will build the system in parts, testing the feasibility at each stage and evaluating affective and cognitive outcomes of each portion. Research questions that will be addressed in the course of this project include: (1) What outcomes associated with use of this GPS-base system could inform future development and implementation? and (2) What contributions do these GPS-based mobile learning applications have on informal science learning as understood within the Six Strands of Informal Science Learning? It is expected knowledge generated in this project will stimulate additional programing for increasing efficacy and use in other widely ranging venues. If successful, it is easy to imagine how this STEM knowledge-building application could be extended for use in other venues across the country.
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TEAM MEMBERS:
Richard FerdigRuoming JinPatrick LorchAnnette Kratcoski
This project examines the design principles by which computer-based science learning experiences for students designed for classroom use can be integrated into virtual worlds that leverage students' learning of science in an informal and collaborative online environment. GeniVille, developed and studied by the Concord Consortium, is the integration of Geniverse, a education based game that develops middle school students' understanding of genetics with Whyville, developed and studied by Numedeon, Inc., an educational virtual word in which students can engage in a wide variety of science activities and games. Genivers has been extensively researched in its implementation in the middle school science classroom. Research on Whyville has focused on how the learning environment supports the voluntary participation of students anywhere and anytime. This project seeks to develop an understanding of how these two interventions can be merged together and to explore mechanisms to create engagement and persistence through incentive structures that are interwoven with the game activities. The project examines the evidence that students in middle schools in Boston learn the genetics content that is the learning objective of GeniVille. The project uses an iterative approach to the modification of Geniverse activites and the Whyville context so that the structured learning environment is accessible to students working collaboratively within the less structured context. The modification and expansion of the genetics activities of the project by which various inheritance patterns of imaginary dragons are studied continues over the course of the first year with pilot data collected from students who voluntarily engage in the game. In the second year of the project, teachers from middle schools in Boston who volunteer to be part of the project will be introduced to the integrated learning environment and will either use the virtual learning environment to teach genetics or will agree to engage their students in their regular instruction. Student outcomes in terms of engagement, persistence and understanding of genetics are measured within the virtual learning environment. Interviews with students are built into the GeniVille environment to gauge student interest. Observations of teachers engaging in GeniVille with their students are conducted as well as interviews with participating teachers. This research and development project provides a resource that blends together students learning in a computer simulation with their working in a collaborative social networking virtual system. The integration of the software system is designed to engage students in learning about genetics in a simulation that has inherent interest to students with a learning environment that is also engaging to them. The project leverages the sorts of learning environments that make the best use of online opportunities for students, bringing rich disciplinary knowledge to educational games. Knowing more about how students collaboratively engage in learning about science in a social networking environment provides information about design principles that have a wide application in the development of new resources for the science classroom.
This project is making novel use of familiar technology (smartphones and tablets) to address the immediate and pressing challenge of affordable, ongoing, large-scale museum evaluation, while encouraging museum visitors to engage deeply with museum content. Using a smartphone app, museum visitors pose questions to a 'virtual scientist' called Dr. Discovery (Dr. D). Dr. D provides answers and the chance to complete fun mini-challenges. The questions visitors ask are gathered in a large database. An analytics system analyzes these data and a password-protected website provides continuous, accessible evaluation data to museum staff, helping them make just-in-time tweaks (or longer term changes) to exhibit-related content (such as multimedia, lecture topics, docent training, experience carts, etc.) as current events and visitors' needs and interests change. The intellectual merit of this project is that it is building evaluation capacity among informal educators, advancing the fields of visitor studies, museum evaluation, informal science learning, and situated engagement, and is contributing to the development of novel evaluation techniques in museums. This project has many broader impacts: The Ask Dr. Discovery system is available to any venue that wishes to use or adapt it to their context. By enhancing the visitor experience and improving museum access to data for evaluation and data-driven decision making across the country, Ask Dr. Discovery has both a direct and indirect impact on museums and visitors of all types. This project is also training the next generation of STEM and education innovators by employing a diverse team of undergraduate students.
The Cyberlearning and Future Learning Technologies Program funds efforts that will help in envisioning the next generation of learning technologies and advancing what we know about how people learn in technology-rich environments. Development and Implementation (DIP) Projects build on proof-of-concept work that showed the possibilities of the proposed new type of learning technology, and project 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 answer questions about how people learn with technology. Although for years researchers have believed technology could afford anytime-anywhere learning, we still don't understand how learners behave differently across contexts, such as home, school, and in the community, and how to get youth to identify as learners across those contexts. This proposal aims to use mobile devices and strategically placed shared kiosks to 'scientize' youth in two low-income communities. Through strategic partnerships with community organizations, educators, and families, the innovation is to get primary and middle-school students engaging in scientific inquiry in the context of their neighborhoods. Research will help determine how the technology can best be deployed, but also answer important questions about how communities can provide support to help kids think like scientists and identify with science. This project will design and implement ubiquitous technology tools that include mobile social media and tangible, community displays (collectively called ScienceKit) that are deeply embedded into two urban neighborhoods, and demonstrate how such ubiquitous technologies and related cyberlearning strategies are vital to improve information flow and coordination across a neighborhood ecosystem, in order to create environments where children can connect their science learning across contexts and time (e.g. scientizing). A program called ScienceEverywhere comprised of partnerships between tightly connected neighborhood organizations with mentors, teachers, parents, and researchers will help learners develop scientifically literate practices both in and out of school, and will demonstrate students' learning to their communities. Research will consist of mixed methods studies of use of the tools, including iterative design-based research, ethnography, and the use of participant observers from the community; these will be triangulated with usage logs of the technologies and content analysis of microblogs by the learners on their identities and interests. Discourse analysis of interviews with focal learners will orient the qualitative work on identity development, and analysis using activity theory will inform the influences of the social practices and sociotechnical systems on learner trajectories. Formative evaluation will help shed light on if and how the sociotechnical system promotes STEM literacy and STEM identity development.
The Cyberlearning and Future Learning Technologies Program funds efforts that support envisioning the future of learning technologies and advancing 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 team aims to explore how to foster learning in socially-networked communities, particularly learning that results in behavior change. Understanding how to foster such learning could have a wide variety of societal impacts, e.g., better fostering science, engineering, mathematical, or design thinking in school or college or on the job, fostering healthy behaviors, helping teens develop pro-social behaviors, and helping people learn to make environmentally-friendly choices as they live their lives. In previous work, this team has developed YardMap, an infrastructure for citizen science that brings together retired adults who are interested in planting and managing their yards in environmentally-friendly ways. YardMap enables social interactions and shared creation of virtual worlds in which participants can try out different ways of managing their yards and see what the downstream effects will be. They also track and display their changing practices and actual yards in ways that are visible to others. YardMap is used by many thousands of participants. In this project, the team is taking YardMap to the next level, using what is known about how people learn and come to change their behaviors to design and refine ways to more directly support individuals in critiquing and improving their behaviors and designs for the common good. What can be learned from the new YardMap will be useful in other fields that focus on helping people change their behaviors in productive ways. The PIs seek to explore how people learn and how to foster learning in socially-networked citizen science communities. Their research addresses how learning happens, how to foster learning, how to design to increase social activity, and how increased interaction with others elevates interest, generates knowledge, and leads to behavior change. Their technological innovation, an infrastructure for citizen science that fosters behavior change, builds on YardMap, an existing infrastructure for citizen science around environmental issues that allows collective data collection and analysis and supports interactive graphing and mapping. Participants design and refine ways of managing their yards in ways that take into account environmental concerns. YardMap enables social interaction and co-creation of a set of virtual worlds for trying out new ideas; learners who are part of the community interact with others in the community, create and refine virtual worlds together, interact with things in the virtual world, manipulate those worlds and collect and analyze data about outcomes, and discuss visual objects that represent real things and practices. As well, individuals track and display their changing practices and actual yards in ways that are visible to others. YardMap can be thought of as a maker movement community focused on yard maintenance; like other maker communities, it encourages participants to create, share and discuss new inventions and practices in a social-networked community setting. Using both what is known about learning in communities and what is known about social drivers of interaction, the team is is extending YardMap to focus on fostering learning and investigating the relationships between learning and behavior change and the influences each has on the other. Much will be learned about how to use social interactions in positive ways to help individuals become more comfortable with behaviors they need to or should take on for health, civic, or educational reasons. What is learned and the technological infrastructure that is created will be directly applicable to other situations where individual behavior changes are needed for change to happen in a social system (e.g., environmental action, changing the culture of an organization, changing norms in a community, perhaps even creating learning communities in formal on-line courses).
This project will help address the urgent need for a new engineering workforce. Middle school students will be entering a workforce that is increasingly global. They will need not only technical skills but also global competencies including: the ability to investigate the world, recognize perspectives, communicate ideas, and take action. This model integrates engineering with global competencies and will provide new knowledge about how this type of learning experience impacts students and educators. This project builds on the success of the previous Design Squad project funded by NSF and developed by WGBH, which has implemented a national model for engineering education for middle school youth. This project expands the model internationally, connecting U.S. based youth with those in Southern Africa (including South Africa, Botswana, and Swaziland). The project partners are FHI 360, a non-profit organization in 60 countries around the world that helps build capacity for improving lives. They will facilitate the implementation of the afterschool programs in Southern Africa . The US dissemination partners include Promise Neighborhoods Institute, Middle Start, Every Hour Counts, and the National Girls Collaborative Project. Project deliverables include a global engineering curriculum; a web platform with videos, games, activities; an afterschool Club Guide; and a Community of Practice for informal engineering educators. A knowledge building component will provide new evidence on how high quality accessible resources and strategies can impact students' development of global competencies and engineering skills to solve real world problems. An iterative approach will be used to develop the resources including the global engineering afterschool curriculum, Club guide, and other components. The methodology uses a continuous cycle of improvement including: assess/design, test/ implement, synthesize/reflect, and utilize/disseminate. The Summative Evaluation will generate evidence about whether and how this kind of collaborative work builds children's understanding of engineering, motivation to participate, and confidence in taking informed action on behalf of pressing global problems. This will contribute to a larger body of work about whether and how engaging with global, collaborative engineering problems leads to greater self-efficacy for children with very different backgrounds, experiences, and opportunities. This project will add new knowledge about how the well-honed Design Squad model in the U.S. can be expanded with a global context and global partners. This proposal was co-funded by EHR/DRL, Engineering/EEC, and International Science and Engineering. During the project period approximately 125,000 children in the US and 5000 children in southern Africa will be reached. In the long term, with the continued global access to the resources, the reach will potentially be in the millions.
The Rutgers Film Bureau in collaboration with the scientists of the LTER (Long Term Ecological Research) project at Palmer will produce a multi-platform documentary project, Antarctic Quest: Racing to Understand a Changing Ocean. This Connecting Researchers to Public Audiences proposal will focus on the scientists who are studying ocean physics, chemistry, biology, and ecology in the West Antarctic Peninsula (WAP), which is the fastest winter warming location on earth. The aim of the project is to promote scientific knowledge about the world's oceans and climate change, inspire interest in scientific careers, as well as train a cadre of next generation film students in the craft of science documentary filmmaking. The project will articulate the research of the Palmer LTER's quest to understand the impact of climate change on the marine ecosystems of the WAP, while involving university students in the filmmaking process. Deliverables include an hour television documentary intended for PBS television broadcast, an online "Antarctic Quest community" created through interactive and interconnected social media, three five-minute educational videos produced for the PBS Learning Media website, and a Digital Media Library to assist Earth science educators. The production team will employ a diverse group of twenty film students from Rutgers University to be involved in the many phases and components of the project. The project is designed to advance the public's environmental literacy. The project will raise awareness of the changes being observed in the world's oceans by illustrating how small changes in the physical conditions in the WAP can have profound impact on marine ecosystems and potentially the entire ocean system. The project will also highlight the significance of innovative new technologies that are revolutionizing research methods as well document the importance of scientific collaboration to understand a complex interdisciplinary problem and the challenges of working in extreme environments. The summative evaluation of the project will assess the effectiveness of the project in meeting its educational goals. By communicating significant scientific research to the public while training a cohort of next generation of science documentary filmmakers, the project will also contribute to capacity-building in the Informal Science Education field.