Families and school-aged constituents at 30 urban, inner-city neighborhood community-based organizations and teachers and students in earth science classes in 40 middle schools. Intent: This project will prepare neighborhood and community leaders in Philadelphia to use simple but effective observation tools and NASA’s educational web content to help their inner-city Philadelphia neighbors learn about space science and technology – and about their city and themselves – by knowledgably exploring the sky. Project Goals: 1. Create multiple opportunities for inner-city children, adults and families to observe and learn about the solar system through neighborhood and city-wide events. 2. Equip CBO’s with the knowledge, skills and materials they need to make space science-related events and activities a sustained part of programming for their constituents. 3. Stimulate interest and engagement in NASA’s missions and resources among residents of traditionally underserved, inner-city neighborhoods through astronomy experiences and NASA’s websites. 4. Create and strengthen collaborative ties between The Franklin Institute, CBO’s, city residents, and local amateur astronomers. Programs/Products produced: 1. Repeatable ‘Galileoscope’ workshops and activities in 30 CBO’s 2. Solar observing activities for 30 CBO’s and 40 middle schools. 3. School assembly-type audience interactive program about observational astronomy for use in schools and community organizations. 4. Recurring neighborhood star parties facilitated through on-going partnerships with local amateur astronomy clubs. 5. Participation in city-wide star party as part of the annual Philadelphia Science Festival.
The goal of this project is to advance STEM education in Hawaii by creating a series of educational products, based on NASA Earth Systems Science, for students (grades 3-5) and general public. Bishop Museum (Honolulu HI) is the lead institution. NASA Goddard Space Flight Center is the primary NASA center involved in the project. Partners include Hawaii Department of Education and a volunteer advisory board. The evaluation team includes Doris Ash Associates (UC Santa Cruz) and Wendy Meluch of Visitor Studies Inc. Key to this project: the NASA STEM Cohort, a team of six current classroom teachers whom the Museum will hire. The cohort will not only develop curricula on NASA earth science systems but also provide guidance to Bishop Museum on creating museum educational programming that best meets the needs of teachers and students. The overall goal of Celestial Islands is to advance STEM education in Hawaii through the use of NASA Earth Science Systems content. Products include: 1) combined digital planetarium/Science on a Sphere® program; 2) traveling version of that program, using a digital planetarium and Magic Planet; 3) curricula; 4) new exhibit at Bishop Museum on NASA ESS; 5) 24 teacher workshops to distribute curricula; 6) 12 community science events. The project's target audience is teachers and students in grades 3-5. Secondary audiences include families and other members of the general public. A total of 545,000 people will be served, including at least 44,000 students.
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.
Bridging Earth and Mars (BEAM): Engineering Robots to Explore the Red Planet engages the general public and K-8 students in exhibits and programs designed to foster awareness of robotic technology, computer programming, and the challenges and opportunities inherent in NASA missions and S-STEM careers. The Saint Louis Science Center (SLSC) of St. Louis, Missouri is the lead institution and project site; partners include Washington University in St. Louis, Saint Louis University, the St. Louis regional FIRST Robotics organization, and the Challenger Learning Center-St. Louis. Project goals are to: 1) inform, engage, and inspire the public to appreciate NASA’s Mission by sharing findings and information about NASA’s missions to Mars; 2) ignite interest in S-STEM topics and careers for diverse K-8 students; and, 3) encourage students in grades 6-8 to sustain participation in educational experiences along the S-STEM careers pipeline. The SLSC will design and build a Martian surface and panorama where two rovers can be remotely controlled. Visitors in the McDonnell Planetarium will use controllers to program rover exploration of the Martian landscape in real-time. Visitors in SLSC’s Cyberville gallery, located one-quarter mile away across a highway-spanning enclosed bridge, will program the second rover with simulated time lag and view its movements via a two-way camera system. SLSC will organize and host a series of Innovation Workshops for K-8 students, each featuring teamwork-building engineering challenges from current and updated NASA-based science curricula. Participants will be recruited from SLSC community partners, which include community centers and faith-based programs for underserved families.
The Mars Exploration Exhibit is a new public exhibition designed to provide experiential learning opportunities for students, educators and the public while inspiring greater excitement about space science. The exhibit emphasizes the importance of STEM education and careers through practical application and inquiry-based learning. Space Center Houston, the official visitor center of Johnson Space Center, is creating the new Mars landscape simulation in partnership with the Houston Independent School District and University of Houston Clear Lake. The exhibit will offer interactive science education activities that will be delivered through distance learning and onsite instruction at Space Center Houston. Utilizing research-based practices in both formal and informal learning environments, the project will help to attract and retain students in science, technology, engineering and mathematics. It will also foster life-long learning and enthusiasm toward the promise of space science and innovation. This unique exhibit will enable students and Space Center Houston’s more than 800,000 annual visitors to increase their knowledge of Earth science and apply their learning to the Mars environment. The exhibit will also highlight the role NASA missions serve in scientific innovation. The project will build the capacity of the Greater Houston community and school-based organizations to engage girls, minorities and other underrepresented students in STEM learning. It will offer in-depth science education for low-performing and gifted/talented students, ultimately bridging achievement gaps, increasing student performance and cultivating greater interest in science. Project outcomes will include: a 1,500-square-foot Mars landscape exhibition; interactive video presentations highlighting water recovery and other environmental processes; a standards-based learning curriculum aligned with Texas Essential Knowledge and Skills (TEKS ) and National Science Standards; and a menu of K-12 experiential learning activities focused on water, air, renewable energy and other critical science topics.
DATE:
-
TEAM MEMBERS:
Janet BrownMelanie JohnsonPaul SpanaMeg Naumann
The Astronomical Society of the Pacific (ASP) and its collaborators are conducting a set of research and development activities focusing on early childhood astronomy in the first field-wide effort to increase the capacity of informal science education (ISE) institutions to effectively engage their youngest visitors (ages 3 - 5) in astronomy. Leading the project is an Action Research Group comprised of the ASP; experts in cognitive development, early childhood, and astronomy learning progressions from UC Santa Cruz, Cal Poly San Luis Obispo, and Penn State; and the Lawrence Hall of Science at UC Berkeley, Children's Discovery Museum of San Jose, and San Luis Obispo Children's Museum as sites for research, field testing, and implementation. The project will identify critical areas of focus for early childhood astronomy and will test the hypothesis that early astronomy learning is not only possible but may contribute to a more sophisticated understanding of the domain. A key question is: How can the ISE field scaffold children's early curiosity and ideas about astronomy to position them for greater understanding and interest in the topic? The results of the research and the materials that are created for educators will receive broad distribution nationally.
Across the globe, citizen science projects are becoming increasingly poised to address social and environmental challenges and answer broad scientific questions. Although rapidly increasing in number, these projects need easy-to-use software tools for data management, analysis, and visualization to be successful. This project transforms how citizen science projects unfold locally, regionally, and globally by creating software that supports the full spectrum of project activities. It empowers projects to ask and answer their own local questions while contributing data critical to larger-scale issues. These tools will allow projects to announce training events; track volunteers; create datasheets; enter, review, analyze, and visualize data; publish reports; discover resources; integrate data; and ensure that data are contributed to repositories (e.g., DataONE, NEON, GBIF, HydroShare, and EOL). Tools will be made available to citizen science projects and will be delivered as reusable software elements for use in existing websites; as website features on CitSci.org; and as Application Programming Interface (API) services and mobile applications. The tools will expand the national reach, local appeal, computational abilities, visualization techniques, statistical analysis capabilities, and interoperability of the nations' cyber-infrastructure. Using participatory design and agile methods, the project will: (1) develop reusable software elements that citizen science organizations can embed into their own websites, (2) harden and expand the functionality and capabilities of CitSci.org through new website features, and (3) extend the APIs of CitSci.org and develop associated mobile applications to increase system and tool interoperability. The target user communities will include citizen science project coordinators. It will deliver customizable tools and services related to all project activities and engage projects across a wide array of disciplines. Project coordinators will be able to customize all tools developed to suit their specific project needs. Adoption and use of the tools developed will create a cyber-ready workforce capable of collecting, contributing, and applying high quality ecological, geophysical, social, and human health related observations to solve real-world problems. These broader impacts will help the citizen science community better understand effective models of public engagement to ensure more impactful application of citizen science to societal challenges.
DATE:
-
TEAM MEMBERS:
Gregory NewmanStacy LynnMelinda Laituri
The Exploring Engagement and Science Identity Through Participation is a research project that examines the outcomes of various citizen science models for Public Participation in Scientific Research (PPSR). The investigation specifically targets citizen science projects that focus on relationships between science learning and science identity. A mixed-method, meta-analysis approach will be employed. The two primary goals of the study are to better understand science learning and science identify within PPSR contexts and to develop a valid Participant Engagement Metric (PEM) for use within PPSR contexts. Data will be collected and analyzed from several PPSR projects and over 4,000 PPSR participants. The project will address several research questions: (1) What are the dimensions of PPSR engagement and how can we measure them across different project models? The research for this question will include approximately 50 interviews of participants in six primary projects representing a range of PPSR approaches to develop and validate a Participant Engagement Metric (PEM) that will be constructed from the frequency, duration and intensity of involvement in key activities. The project will use a constant comparative method of data analysis (processing of data as they are gathered in order to compare them with emerging categories. The development of the PEM will be one concrete outcome of the proposed research. (2) Within and among projects, what is the relationship between participant engagement and individual learning outcomes? The project will use validated measures of learning outcomes derived from Learning Science in Informal Environments (NRC, 2009) and developed for the DEVISE project described below. The six measures include: Behavior & Stewardship, Skills of Science Inquiry, Knowledge of the Nature of Science, Interest in Science & the Environment, Efficacy, and Motivation. The proposed research will look at how engagement affects learning outcomes, as assessed by these six measures (science interest, efficacy, etc.). The project will conduct participant surveys in the six participating citizen science projects in addition to several other PPSR projects to test the relationship of the PEM and other measures of activity involvement to the learning outcomes measured by the survey instruments developed and validated through a previous project. The data analysis will begin with univariate summary statistics that will provide an overview of the basic dataset. Inferential statistics including multiple regression analysis will be used to test the relationships among the independent variables (type of PPSR project, demographics), PEM as a mediator variable, and the dependent variables. (3) How does degree and quality of participation in scientific research develop and/or reinforce individual science identity? The project will conduct a 3-year longitudinal study using surveys, a series of in-depth interviews, and on-site observations of 36 participants from the six primary projects to understand the development of individual science identity within PPSR environments over time. Quantitative and qualitative data and findings will be "triangulated" to determine if convergent, inconsistent or complementary results can be identified. The project proposes a strong dissemination plan, using these approaches, to present research in journals, disseminate research briefs, host online forums, and launching various listserves and online forums at the citizenscience.org website.
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.
Living Liquid is a full-scale development project that will develop and research a new genre of science exhibit that engage visitors in inquiry with large scientific datasets through interactive visualizations. Building on findings from a prior pathways project, Living Liquid will develop three interactive visualizations on a multi-touch Viz Table with a tangible user interface. Each visualization will support visitors in the exploration of a dataset provided by the project’s science partners: 1) Plankton Patterns will show how the ocean is defined by regions of microscopic life using data from the MIT Darwin Project; 2) Ocean Tracks will reveal the “highways” large marine creatures travel with data from the TOPP project at Stanford University; and 3) Genetic Rhythms will follow the activity of marine creatures’ genes in response to environmental conditions based on data from the Center for Microbial Oceanography Research and Education (C-MORE). Through an iterative process of collaborative research and development among museum professionals, educational researchers, computer scientists, marine biologists, data artists and interaction designers, this project seeks to: (1) Advance public understanding of ocean ecosystems and large data inquiry skills through the development of a Viz Table. (2) Advance STEM professionals’ knowledge of how to engage the public in inquiry with visualizations through an educational research study. (3) Increase the capacity of STEM professionals (both ISE developers and research scientists) to develop visualizations through a collaborative development process that includes graduate student training and residencies.
Brigham Young University and the University of Maryland, in partnership with the Smithsonian Institution, the Computer History Museum, and NASA, plus leading game designers, educators, scientists, and researchers, will conduct research on the design and development of two large-scale Alternate Reality Games (ARGs) based on deep-time science in astrobiology, astrophysics, and interplanetary space travel. The project will iteratively design and test two distinct types of ARGs (closed- and open-ended) to study the effects of these ARGs on STEM learning. The ARGs will be based upon the Next Generation Science Standards (NGSS), affording learners with intensive, self-driven, and scaffolded scientific learning and will be aimed at attracting girls and other groups historically underrepresented in science and technology. Each ARG will be designed by NASA scientists, educators and education researchers, and game-based learning experts and will be highly interactive: engaging learners in collaborative investigations in real and virtual worlds to collect scientific data, conduct data analysis, and contribute scientific evidence that will help solve scientific questions within a science-based narrative derived from real world problems that will develop learners' computational thinking skills in a collaborative, participatory virtual learning environment. Combining data from web and social media analytics, player interviews, surveys, and user-generated content, researchers, and evaluation experts at UXR who will provide an outcomes-based evaluation, including front-end, formative, remedial, and summative evaluations, will establish the properties of ARGs that most effectively advance informal STEM learning outcomes. By comparing open-ended and closed-ended ARGs, the PIs will be able to assess the relative strengths and weaknesses of two distinct approaches to Alternate Reality Game design. The project team will test the hypothesis that open-ended, user-generated content will support inquiry-based learning, peer-to-peer learning, and life-wide and life-deep learning, while close-ended, narrative-rich ARGs will support specific transfer of STEM knowledge, collaboration, and problem solving. To help ensure that the games appeal to their target audiences, the project team will adopt co-design methods, enlisting the creative input of participating teens at each stage of the design process. Supplementary materials and lesson plans developed in close consultation with teachers, librarians, teens, and external stakeholders will enable the ARGs to be widely and effectively used as a model in museums, classrooms, libraries, and after-school programs. The proposed ARGs represent a unique environment to test learning principles that enable players to bridge their learning through transmedia across multiple contexts and test the effects of collaboration with massive numbers of concurrent players. As a result, the project should yield insights on how learning principles can be adopted and re-appropriated for emerging learning environments, including those that that might be crowd-sourced. The research is well grounded in the literature and the PIs do an excellent job of mapping ARG design principles to the pertinent learning science research, providing a clear sense of the particular affordances of the genre that should lead to new understandings. The approach has profound implications for the way we might teach the next generation of students. The ability to mix problem solving and learning in virtual spaces with experiences and data derived from the physical world could dramatically change how we understand the role of technology in education.
This project from the University of Florida proposes to derive and develop a network and community of practice (CoP) among amateur and professional paleontologists across the country. Should this project be successful, it would put together 40 professional Paleontologist with 23 amateur Paleontology clubs across the country. The advantage of this organization would be to facilitate sharing of specimens (digitally on the web), educating each other, and most important, making the public outreach from each club more effective. While each club has specimens, this network would provide access to over 100 million digitized samples. The web-base for this collection will be managed at the University of Florida under the direction of the PI. The research portion of this project will determine what the essential elements necessary are for effective learning between professionals and amateurs and how the CoP enhances amateur learning and outreach efficacy. The project plan includes a centralized organization to initially form the community of practice, call general meetings, publish newsletters and organized a large meeting at the University of Florida in the coming year. Further, the project team will conduct evaluation on how the project is helping members develop and how the organization can be improved. Educating individuals in the field of paleontology is generally a positive experience. This project will facilitate knowledge building among the individual members of the clubs, which will enhance their perspective and enable them to reach out to members of their communities. The project will be evaluated at every level to ensure that the existing clubs are incorporated into the project and new clubs are welcomed and engaged as well.