Who We Are: A network of informal educators, climate scientists, learning scientists and local partners across four cities, dedicated to improving local understanding of and engagement with climate change science. Mission: CUSP aims to foster a network of climate-focused organizations to implement targeted, coordinated, and concentrated educational strategies that explore local climate impacts and community-level responses. What We Do: Unite local organizations committed to addressing the impacts of climate change into collaborative network Use latest climate science and learning science research to inform program development Connect urban residents’ personal interests to larger city systems impacted by climate change, and provide residents opportunities to explore city-wide responses Deliver programs that are targeted (aimed at specific audiences), coordinated (presenting consistent and clear information about the science of climate change), and concentrated (delivered many times, through many programs) Test the hypothesis that when people encounter the same science content in multiple settings, from multiple points of view, they are more likely to understand and remember important concepts What We Offer: A Community of Practice for local organizations, including training on best practices of climate communication and education Provide local organizations with current climate science impacting their city, and latest learning science research Opportunities for city residents to explore local impacts of climate change in every day settings, at neighborhood centers, at schools, online, and at city festivals. Opportunities for city residents to engage with local organizations in community-level responses to climate change
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TEAM MEMBERS:
The Franklin InstituteRaluca EllisFrederic BertleySteven SnyderRadley HortonKevin Crowley
This is a Broad Implementation proposal. Our goal is to create a vibrant, sustained community of practice around the established Café Scientifique New Mexico model for engaging high school teens in science, technology, engineering and math; scale-up will be accomplished via a national network of committed partners. The adult Cafe Scientifique model for engaging citizens in science has proven very effective and has been implemented widely. The interaction in a social setting with a scientist-presenter around a hot science topic is the key to the model’s success. With ISE funding, the model has been adapted by Science Education Solutions for the high school teen audience. Cafe Scientifique New Mexico, now starting its fifth year, has had documented success in providing teens with increased STEM literacy and a more realistic picture of scientists as real people leading interesting lives. Teens come to better understand the nature of science and are more likely to see the relevance of science to their lives. Scientists express strong satisfaction with the nature of our coaching and the resulting quality of their science communication. The program has been continually evaluated and improved, and is now ready for broad implementation. Intellectual Merit: Teenagers are the adult citizens and workforce of tomorrow. Teens are reaching a critical life juncture and are making choices that affect their future life style, life-long learning behaviors, and careers. Yet they are increasingly dropping out of the STEM pipeline in school. Even teens interested in STEM often know little about science and engineering careers and the nature of scientific research. Teen Cafés can play an important role in addressing these challenges. We have two major objectives: 1. Implement the Café Scientifique model of Teen Cafés in a national network of sites committed to adopting and adapting the program and validating its impacts with diverse audiences; and 2. Create a vibrant and sustainable community of practice comprised of ISE and STEM professionals interested in engaging teens in STEM through Teen Cafés. We have formed a core network of six initial partners: Southern Illinois University Edwardsville, Center for STEM Research, Education, and Outreach; The Florida Teen SciCafé Partnership; North Carolina Museum of Natural Sciences, Raleigh; Science Discovery, University of Colorado; The Pacific Science Center in Seattle; and The Missouri AfterSchool Network (MASN) – Project LIFTOF. We will add two more core partners in Year 3. The core partners will join the Teen Cafe Network in a staged fashion in years 1 - 3. Each will reach sustainability over a three-year funding period. Each node has a local area network of partners consisting of organizations that will host local Cafes; scientific organizations with potential presenters; schools and other organizations for recruiting teens; and entities capable of contributing to financial sustainability. The network will provide a structure for a dynamic, growing, and sustainable community of practice to implement the Teen Café model, in which high school teens will gain skills in scientific discourse, thought, and exploration. STEM professionals will gain improved skills for communicating with public audiences and a new perspective on their research from a broader societal perspective. ISE professionals will gain capacity to adapt, implement, test, and further disseminate the Teen Café model and increased capability for preparing STEM experts to communicate effectively with teen audiences, along with tools, resources, and expertise to help them do so. Science Education Solutions will manage the project and provide the resources to support the community of practice, while continuing Cafe Scientifique New Mexico as a ninth network node. We will stimulate intensive ongoing communication of lessons learned across the network as partners start up their Cafe programs; external observers will be able to watch the program unfold. Broader Impacts: We will build capacity for serving teens and effective communication of science in the broad ISE and STEM communities by encouraging and nurturing others wishing to start a Cafe program and join the network. We have partnered with 10 large science and science education organizations, each with its own extensive network, which will allow us to further propagate the Teen Cafe Network. They are: National Ecological Observatory Network (NEON). Nanoscale Informal Science Education Network (NISE Net), The American Institute of Physics (AIP), Science Cafés.org (to include NOVA), Science Festival Alliance, Consortium of Universities for the Advancement of Hydrologic Science (CUAHSI), Informalscience.org, Project Liftoff: Elevating Science Afterschool, ITEST Learning Resource Center, and The Center for Multiscale Modeling of Atmospheric Processes (CMMAP). Each partner will also target underserved and diverse teen audiences for their programs.
Indianapolis / City as Living Laboratory (I/CaLL) is a city-wide civic collaboration engaging in cross-sector research that builds on prior research in informal science learning in public settings. It extends research in place-based and service learning traditions, and uses the city itself as an informal science learning (ISL) environment for Science and Engineering for Environmental Sustainability learning outcomes. This project is creating place-based science learning experiences as part of public spaces in Indianapolis and establishes the next generation of urban science museums that increase opportunities for learning. The project will develop a self-sustaining program for art/science collaborations as they inaugurate city-sanctioned changeable installations at I/CaLL sites. Data from the project will be used to inform ISL professionals at museums throughout the community and around the country. Thousands of volunteers and their families will help create I/CaLL spaces, engage with communities, and serve as research participants connecting with science learning through site development. The unprecedented scale of this project provides a full measure of informal science service learning at a city scale, offering data that can change how science learning is measured, how people from all walks of life develop science literacy as part of their social public experience, and embodying the concept of the city as a living science learning lab. Broader impacts include the development of the city as an informal science learning environment that will become a new standard for thinking about what cities as cultural units can become as we build a resilient Science and Engineering culture for Environmental Sustainability.
This full-scale development project will address the need for creative models to support STEM learning in underserved rural communities that lack traditional infrastructure such as science centers. The project will create and study an innovative model of capacity-building: viz., small networks of community-embedded “STEM Guides” will be trained to identify a range of existing STEM resources available in their local regions, and to connect STEM-interested youth with them in creative and personal ways. Anticipated learning outcomes for youth and families include greater awareness of and interest in STEM experiences and pathways. At the regional level, the project will build capacity through increasing the STEM Guides’ knowledge of local STEM opportunities, and by enhancing connections among STEM-related resources, programs, and industries. The project will implement and study STEM Guide networks in a staggered series of five low-income, rural regions, providing startup resources and professional development. The project will increase the frequency and depth of out-of-school STEM experiences for approximately 3,000 youth aged 10-18 at a relatively low cost, creating a national model for STEM capacity-building in rural settings. It is led by the Maine Mathematics and Science Alliance, with 4-H, Cornerstones of Science (library-based STEM) and Maine’s university system as collaborators. EDC is the primary external evaluator.
The Badges for College Credit project designs and researches: (1) a digital badge system that leads to college credit as the context for investigating how to integrate badges with learning programs; (2) how to assess learning associated with badges; and (3) how badges facilitate learning pathways and contribute to science identity formation. The project is one of the first efforts to develop a system to associate informal science learning with college credit. The project will partner with three regional informal science institutions, the Pacific Science Center, the Future of Flight, and the Seattle of Aquarium, that will facilitate activities for participants that are linked to informal science learning and earning badges. The project uses the iRemix platform, a social learning platform, as a delivery system to direct participants to materials, resources, and activities that support the learning goals of the project. Badges earned within the system can be exported to the Mozilla Open Badges platform. Participants can earn three types of badges, automatic (based on participation), community (based on contributions to building the online community), and skill (based on mastery of science and communication) badges. Using a learning ecologies framework, the project will investigate multiple influences on how and why youth participate in science learning and making decisions. Project research uses a qualitative and quantitative approach, including observations, interviews, case studies, surveys, and learning analytics data, and data analytics. Project evaluation will focus on the nature and function of the collaboration, and on the scale-up aspects of the innovation and expansion, by: (1) analyzing and documenting effective procedures,and optimal contexts for the dissemination of the model and (2) by analyzing the collaboration between informal science organizations and higher education.
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Carrie TzouKaren LennonAmanda GoertzGray Kochlar-Lindgren
The project is designed to engage Hispanic students in grades K-5 in STEM in afterschool programs within community-based organizations (CBOs). The project builds on the foundation of an NSF-supported afterschool science program--APEX (Afterschool Program Exploring Science). In collaboration with National Council of La Raza (NCLR), and ASPIRA, the project adapts APEX into a bilingual English/Spanish format and, using a train the trainer model, disseminates it nationally, using a train the trainer model. Each of the ten local project sites will build on a partnership between a science museum and a CBO affiliate of NCLR or ASPIRA. The project is designed to: (1) Build the organizational capacity of partner science museums to work with CBOs and the Hispanic community. (2) Strengthen links between science museums and Hispanic serving CBOs in their communities. (3) Engage the expertise, involvement, and collaboration of national Hispanic-serving organizations, NCLR and ASPIRA, in STEM education. (4) Increase the engagement of Hispanic children and families in STEM. The project evaluation will investigate how effectively the project builds the organizational capacity of partner museums and CBOs in engaging Hispanic children and families in STEM; the types and strength of science museum/CBO partnerships; the effectiveness of the project in increasing Hispanic student and family engagement in STEM, and the types of contributions the project makes to the field of informal STEM learning. The evaluation will use qualitative and quantitative methods, including surveys, interviews, case studies, social network and collaboration analysis, observations, activity tracking, embedded assessment, photo elicitation, and focus groups.
Techbridge has proposed a broad implementation project that will scale up a tested multi-faceted model that increases girls' interest in STEM careers. The objectives of this project are to increase girls' engineering, technology, and science skills and career interests; build STEM capacity and sustainability across communities; enhance STEM and career exploration for underrepresented girls and their families; and advance research on the scale-up, sustainability, and impact of the model with career exploration. The Techbridge approach is grounded in Eccles' expectancy value model, and helps bridge critical junctures as girls transition from elementary to middle school and middle school to high school, immersing participants in a network of peers and supportive adults. Techbridge targets girls in grades 5-12 with a model that includes five components: a previously tested and evaluated curriculum, career exploration, professional development for staff and teachers, family engagement, and dissemination. The inquiry-based curriculum introduces electrical engineering and computer science through engaging, hands-on units on Cars and Engines, Green Design, and Electrical Engineering. The Techbridge model will be enhanced to include a central repository for curriculum and support materials, electronic girl-driven career exploration resources, an online learning community and video tools for staff, and customized family guides. Project deliverables include the dissemination of the enhanced model to three cities, 24 school sites and teachers, 2,000 girls, and over 600 role models. A supplementary research component will study the broad implementation of the Techbridge model by examining the fidelity of implementation and the program's impact on girls' STEM engagement and learning. The research questions are as follows: (1) To what extent and how do new program sites demonstrate adherence to the Techbridge program model? (2) Do new sites experience similar or increased participant responsiveness to Techbridge programming with regard to scientific learning outcomes, career awareness, attitude and interest in engineering? (3)How are changes experienced by girls sustained over time, if at all? (4) To what extent and how do new sites balance instilling the Techbridge essentials, those critical components Techbridge identifies as essential for success, with the need for local adaptation and ownership of the program? and (5) Given the potential for customization in local communities, do new sites maintain programmatic quality of delivery experienced at the original site? If so, what are elements essential to success regarding quality delivery? The mixed-methods study will include document analysis, embedded assessments, participant survey scales, and observations. Qualitative data methods include interviews with teachers, role models, staff and focus groups with girls. A project evaluation will also be conducted which investigates project outcomes for participants (girls, teachers, role models, and families) and fidelity of the implementation and enhancements at expansion sites, using a quasi-experimental approach. Career and learning outcomes for girls will be determined using embedded assessments, portfolios, surveys, school data, and previously validated instruments such as the Career Interest Questionnaire and the Modified Attitudes towards Science Inventory. The Managing Complex Change model is used as a framework for the project evaluation for the purpose of examining factors related to the effectiveness of scaling. The dissemination of research and evaluation findings will be achieved through the use of publications, blogs, social media, and conferences. It is anticipated that this project will broaden the participation of Hispanic, African-American, and English language learner girls, build capacity for STEM programming and sustainability at the dissemination sites, and disseminate findings to over 1 million educators, researchers, and community members. Broader impacts include contributing to the field's understanding of how virtual role models and field trips can engage young women, increase corporate advocacy, and engage participants in research and dissemination efforts.
This CAREER proposal focuses on the development of teachers' identities, which are operationalized as beliefs and practices, behaviors, and pedagogical knowledge. The PI uses a qualitative approach, occurring over two phases, to investigate the impact of formal-informal collaborations on identity development over time. The study is grounded in an ecological theoretical approach that incorporates a view of informal learning settings as learner-driven and unique in providing opportunities for interaction with objects during meaning-making experiences among groups of learners. The longitudinal research design includes collection of an array of data, including observations of teaching and learning activities, interviews, survey responses, and archival documents such as student work and videos of classroom experiences. The PI uses a narrative analysis and a grounded theoretical approach to generate themes about beliefs and practices around behaviors and pedagogical knowledge informed by informal science education experiences. Research findings and related educational activities inform the field's understanding of best practices of integrating informal science activities into science teacher education, including determining appropriate kinds of support for STEM teachers who learn to teach in informal learning environments (ILE). The PI is integrating research findings in the revision of existing courses and the development of new courses and experiences for both new and experienced teachers. The project addresses the need for empirical evidence of impacts of ILE experiences on professional development, and will build capacity of informal science institution and university professionals to provide effective teacher education experiences and new teacher support.
This project's interdisciplinary team will carry out research and training that will identify ways for professionals in science, technology, engineering, and mathematics (STEM) to engage with public audiences that currently lack the community connections, resources, time, or know-how to gain access to science education and to scientists. The project will create real and on-line materials for scientists to convey the excitement, content, and relevance of their own research to public groups whose values, professions, or aesthetic and cultural backgrounds are connected to that research topic. The project will also foster ways for scientists to understand that members of the public can provide valuable input to science. Research and evaluation on the development of this innovative public engagement model "the STEM Ambassador Program (STEMAP)" will be conducted to provide insights into the effectiveness and extensibility of the STEMAP model. This approach integrates three existing elements of science engagement that have previously not been linked: design thinking, informal science education communication skills from museum work, and connecting scientists' research with the existing values of particular community groups. Robust evaluation will enhance effectiveness of in-person and online trainings; research will provide understanding of how different science learning models can be integrated and enhanced for public audiences and for scientists. This 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. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. Science and society need innovative and transformative ways to interact synergistically. Given the deep knowledge and contagious passion for their research, STEM professionals can bring unique assets to directly engage public audiences, especially important the traditionally underserved public groups. Members of the public in turn have the potential to provide novel ideas, data, and insights to support researchers. The project's exploratory research will help understand how STEM professionals can broaden participation by themselves engaging unengaged publics with the excitement of science and science knowledge in ways that are congruent with academic rewards. The project team will integrate three existing NSF-funded models: a) Research Ambassador Program, b) Portal to the Public, and c) Design Thinking. A cadre of faculty and graduate students will be trained in "STEM Ambassadors" workshops, in which social scientists and community group representatives will help STEM Ambassadors identify public groups with interests that connect to the scientist's research. Engagement events will occur in community venues, e.g., churches, factories, and day care centers, etc. Case studies and evaluation instruments answer research questions about: the role of empathy in the formation and change of identity; relationships between public audiences, mode of engagement, and identity shifts; and motivational drivers for STEM Ambassadors and public audiences. The intellectual merit is the training and evaluating of 50 STEM Ambassadors (via 100 outreach events involving approximately 5000 individuals from community groups); strategies that encourage STEM professionals to engage with underrepresented publics; and insights on how to integrate multiple education models. STEMAP will disseminate its findings and new resources through the STEMAP website. In addition, the dissemination efforts will be extended through: collaboration with the NSF-funded PoPNet Expansion Project and the Centers for Science and Mathematics Education (CSMEs); presentations at national science professional organizations, such as the AAAS, as well as through the CAISE Wiki and the National Alliance for Broader Impacts (NABI). STEMAP will create a process for other NSF PIs to generate, evaluate, and articulate their research and its applications to public groups that lie far outside academia.
Arizona State University will develop new features for its SciStarter website that will expand participation in citizen science and provide rich data for researching the nature of and impacts of citizen science participation. SciStarter is a popular online citizen science hotspot featuring more than 850 searchable citizen science projects, added by researchers and project owners, and serving over 35,000 citizen scientists. The project will develop new features to add to the current website that will enable participants to explore hundreds of citizen science projects and select projects of most interest to them, track their participation, and connect to people and projects they are interested in. The expanded website will also provide rich data that will help citizen science projects evaluate their programs and that will rich data for researchers to investigate the nature of citizen science participation. The website will be widely accessible to the public through partnerships with Discover Magazine, the Citizen Science Association, and other partners. The SciStarter website will develop additional features to expand citizen science participation and to research the nature and impacts of participation. The expanded features will include: (1) an integrated registration for participants to more easily engage in one or multiple citizen science projects, across platforms; (2) GIS implementation for project owners to define the geographic boundaries of projects so participants can find them more easily; and (3) an online, personal dashboard for participants to track their projects, participation, and contributions to science, share and save data, record interests in projects, create profiles, and find people and projects of interest to them. These new features will create opportunities for future research concerning: (1) understanding how citizen scientists use the site and how it responds to their needs and interests, and (2) understanding why, how, and with what impacts citizen scientists participate in research. The project will support the overall strategy of the Advancing Informal STEM Learning Program to enhance learning in informal environments through the funding of innovative resources through a variety of settings. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants.
The Seeing Scientifically project will research a new way of supporting museum visitor experiences so they can have authentic scientific observation of live microscopic specimens. By adapting existing computational imaging techniques from current biological research, the project aims to encourage and support visitors in observing scientifically, that is, in asking productive questions, interpreting image-rich information, and making inferences from visual evidence that increasingly characterizes current biological research. The scaffolding (e.g., visual cues or information supporting learning) will consist of a system of virtual guides and prompts that are responsive to what visitors see. The scaffolding prompts will be overlaid on a real time, high-density image of a live sample that the visitor is investigating with a research grade microscope. Project research will contribute early knowledge on ways to scaffold informal learners in the practice of authentic scientific observation with the complex, dynamic visual evidence that scientists themselves see using the equipment and techniques they use. Project research and resources will be widely disseminated to learning science researchers, informal science practitioners, and other interested audiences through publications, conference presentations and sharing of resources via the NSF-supported informalscience.org website and other relevant websites. 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 includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. The project will prototype an innovative microscope exhibit that scaffolds visitors in scientific observation of live specimens and their biological processes. The overarching hypothesis is that scientific observation of real-time visual phenomena can deeply engage learners with the content, tools and practices of modern science, which increasingly rely on image-based data. Through three rounds of iterative prototype development and evaluation, the project will generate early findings for the following related questions: (1) what are promising ways of scaffolding observation of live specimens at an unmediated exhibit; (2) How can computational imaging techniques be integrated into a microscope exhibit to engage and scaffold learners to ask productive questions, interpret what they see, and make evidence-based inferences from complex, dynamic images. Data will be collected and analyzed by coding think-aloud interviews with visitors concerning their interest in and description of the biological phenomenon observed; coding of think aloud transcripts of visitor questions types and answers, relevant features noted, inferences and scaffold use; and statistical comparison of holding time, questions asked, answers, inferences, and scaffold use. Project findings will seed more rigorous research on the combination of scaffolding and computational imaging techniques effective for supporting scientific observation in image-rich areas of science.
The Advancing Informal STEM Learning (AISL) program funds innovative projects in a variety of informal settings. The iSWOOP project aims to equip National Park Service interpretive rangers with visualizations and interactive approaches for communicating science in natural learning spaces. An advantage to locating STEM learning in national parks is that they serve as America’s outdoor laboratories, hosting thousands of research studies annually. Dynamic changes in the landscape, wildlife, and interspecies interactions offer countless avenues for inquiry. The project will build collaborations between park-based scientists, whose work frequently happens out of the public eye, and interpreters, who interact with millions of visitors annually. Based on pilot studies done at Carlsbad Caverns National Park, the researchers have extended this work to four more national park units, each with its own natural resources and research. Partners in this endeavor include Winston-Salem State University, Institute for Learning Innovation, and TERC. This project's goal is to establish a model for how national parks can be resources for science education and learning.
iSWOOP works by providing interpretive rangers with professional development. iSWOOP coordinates 1) opportunities for interpreters and scientists to work together in a classroom setting and in the field; 2) creates compelling visualizations, which can function as a jumping off point for conversations about the methods and relevance of park-based research; 3) ongoing opportunities for interpretive rangers to reflect on interactions with visitors and to experiment with questions that spark visitors’ curiosity in the moment and interest long-term.
The main goal of this proposed effort is to translate park-based research endeavors and results from the scientists to the park visitors in ways that make the process enjoyable, informative, and thought-provoking. Evaluation elements will be included every step in this process in order to not only determine if learning has occurred but also how effectively the science has been translated.