Our goal is to demonstrate an educational model fully commensurate with the demands of the 21st Century workforce, and more specifically, with the emerging “green-tech” economy. We recognize a pressing need creating more sustainable solutions for the (human) built-environment and of stabilizing economic patterns that uphold sustainable systems. to prepare citizens for the challenges of The ASCEND model is designed to encourage these societal shifts, but at the same time, it is an attempt to put theory into practice - activating educational practices aligned with research on human development and cognition. For some time now strong recommendations for apprenticeship learning have emphasized the function of legitimate peripheral participation – the possibility of which becomes more prevalent in robust communities of practice. As compared to top-down approaches (typical of formal education settings) these "learning communities" are seen as being more closely aligned with our natural propensities for learning and cognition. ASCEND represents a design-experiment -an attempt to learn how we can create and sustain opportunities for apprenticeship learning in an interdisciplinary arena at the leading edge of technical innovation. In addition, the ASCEND model introduces and examines the efficacy of “digital storytelling” as an alternative to more traditional forms of apprenticeship learning and as a means to engage and advance this and future generations in STEM. A further goal is to develop innovative measures of assessment commensurate with this new model of apprenticeship learning. Finally ASCEND explore how informal learning organizations (museums, libraries, preserves etc.) can use digital storytelling to develop community-driven programs inclusive of at-risk youth and other hard to reach audiences.
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.
This three-year research project will study the impact of science center staff facilitation strategies in the area of mathematics learning in a museum exhibit environment. The three main deliverables are: (1) Iteratively developing and refining a theoretical model of how staff facilitation can deepen and extend family mathematical discourse at interactive exhibits; (2) Rigorously testing key components of this model, including the relationship between staff facilitation and the nature of family mathematical discourse; and (3) Providing evidence and research-based tools to support PD efforts for informal STEM educators. The project will leverage the success of the NSF-funded Access Algebra project (DRL-0714634) to advance the field's understanding of socially mediated, informal math learning and identify effective, evidence-based facilitation approaches. The project's research will build from theoretical notion of sociomathematical norms (Yackel & Cobb, 1996), which is currently based on classroom research. A key element of the project will be to determine whether and how, the norms can be applied to informal learning environments. The first phase of the project begins with a qualitative, design-based research (DBR) study to develop a theoretical model of staff-facilitated family math learning, including staff facilitation strategies that support family mathematical discourse and contextual factors that influence that discourse. In the second phase of the project, the team will use an experimental approach to rigorously test the staff facilitation model developed during Phase 1. This mixed-method design will allow the team to both study the complexities of informal math learning and rigorously test causal connections between staff facilitation and the level of family math discourse. Finally, the project staff will provide tools to support PD efforts for informal STEM educators across the country.
This Pathways project from the Ocean Discovery Institute (ODI) seeks to develop and pilot a program model designed to fill an identified gap in citizen science research and practice literature: how to effectively engage and better understand how to foster participation among people from under-represented groups in citizen science research. The ODI model is designed around six principles: (1) leaders who are reflective of the community, (2) science that is locally relevant, (3) guided, as opposed to self-guided, experiences, (4) direct interactions with scientists, (5) progressively increasing responsibilities for participants who express interest, and (6) removing barriers to participation, such as transportation, language, family involvement and access to technology. The project addresses environmentally degraded, crime-ridden local canyons, a locally relevant STEM-related issue, and leverages the Southern California Coastal Water Research Project's (SCCWRP) regional citizen science effort focused on identifying the sources and pathways of trash through regional watersheds. The scientific research components of the project focus on four canyons in the area, employing sampling methods developed by SCCWRP. Youth who are part of other ODI programs and who have demonstrated leadership and interest in science, work with the project team to scaffold family and youth participation in project activities taking place during afterschool and weekend time. Based on continued participation in the project, community participants can become more involved in the project, starting as "new scientists" and moving through "returning scientists" to "expert scientists" roles. The project evaluation seeks to identify the role and importance of the components of the proposed model with respect to participation, retention, and learning by participants from groups under-represented in STEM. The dissemination products of this Pathways project include a white paper describing the model and lessons learned as well as presentations to community groups and education and citizen science practitioners. Based on insights from the iterative approach to the model during this Pathways study, a subsequent full-scale development project would seek to engage citizen science projects around the nation in adapting the model to increase participation of individuals from groups underrepresented in STEM, including building out ODI's citizen science programming.
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TEAM MEMBERS:
Lindsay GoodwinRoxanne RuzicTheresa Sinicrope Talley
The University of Texas at El Paso will conduct a research project that implements and documents the impact of co-generative dialogues on youth learning and youth-scientist interactions as part of a STEM research program (i.e., Work with A Scientist Program). Co-generative dialogues seek to specifically assist with communication and understanding among collaborators. Over four years, 108 11th grade youth from a predominantly (90%) Hispanic high school will conduct STEM research with twelve scientists/engineers (e.g., chemist, civil engineer, geologist, biologist) and undergraduate/graduate students as part of 7 month-long after school program, including bi-weekly Saturday activities for 5 months followed by an intensive month-long, self-directed research project in the summer. Youth will be randomly assigned to experimental groups that include the co-generative dialogue treatment and control groups without the intervention. The scientists and their STEM undergraduate/graduate students will participate in both experimental and control groups, with different youth. Youth will receive high school credit to encourage participation and retention. The PI team hypothesizes that co-generative dialogues will result in improved learning, communication, and research experiences for both youth and scientists. Educational researchers will conduct co-generative dialogues, observations, interviews, and surveys using validated instruments to address the following research goals: (1) To investigate the impact of the treatment (co-generative dialogues) on youth knowledge, attitudes, perceptions of their experience, and their relationships with the scientists; (2) To investigate the impact of the treatment on scientists and graduate students; and (3) To identify critical components of the treatment that affect youth-scientist interactions. It is anticipated that, in addition to providing in-depth STEM research experiences for 108 youth from underrepresented groups at a critical time in their lives, the project will result in widely applicable understandings of how pedagogical approaches affect both youth learning and scientist experiences. The project also seeks to bridge learning environments: informal, formal, university and digital.
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 National Research Council's (NRC) Board on Science Education will identify an expert study committee to develop a report identifying the criteria for successful out-of-school STEM learning based on evidence from successful practice. The committee will be informed by commissioned papers and by a 2-day public workshop that explores the current evidence. The report will be written for policy-makers, funders, non-profit and private industry representatives, and other representatives from civic society. The primary goal of the report will be to help these audiences better understand and more strategically support investments in out-of-school STEM education, and to encourage partnerships that promote the linking of out-of-school STEM learning to school-based learning. This study complements the NRC work done to produce the Successful K-12 STEM Education report and builds from prior NRC studies, especially Learning Science in Informal Environments, Surrounded by Science and Education for Work and Life: Developing Transferable Knowledge and Skills in the 21st Century.
This full-scale project addresses the need for more youth, especially girls, to pursue an interest in engineering and eventually fill a critical workforce need. The project leverages museum-based exhibits, girls' activity groups, and social media to enhance participants' engineering-related interests and identities. The project includes the following bilingual deliverables: (1) Creative Solutions programming will engage girls in group oriented engineering activities at partner community-based organizations, where the activities highlight altruistic, personally relevant, and social aspects of engineering. Existing community groups will use the activities in their regular meeting structure. Visits to the museum exhibits, titled Design Your World will reinforce messages; (2) Design Your World Exhibits will serve as a community hub at two ISE institutions (Oregon Museum of Science and Industry and the Hatfield Marine Science Center). They will leverage existing NSF-funded Engineer It! (DRL-9803989) exhibits redesigned to attract, engage, and mobilize a more diverse population by showcasing altruistic, personally relevant, and social aspects of engineering; (3) Digital engagement through targeted use of social media will complement program and exhibit content and be an online portal for groups engaged in the project; (4) A community action group (CAG) will provide professional development opportunities to stakeholders interested in girls' STEM identity (e.g. parents, STEM-based business professionals) to promote effective engineering messaging throughout the community and engage them in supporting project participants; and (5) Longitudinal research will explore how girls construct and negotiate engineering-related identities through discourse across the project activities and over time.
This research project establishes a new research center, the InforMath Collaborative, that brings together university educational researchers and professionals at art and science museums in San Diego's Balboa Park. The InforMath Collaborative is investigating and building the capacity of informal learning institutions to support content and identity learning in mathematics. Through sustained collaborations that unite research, design, and professional development, members of the InforMath Collaborative are conducting design-based research on exhibits and programs that integrate art and science content from participating museums with the mathematics of topology and projective geometry.
The broader goal of the InforMath Collaborative is to transform cultural perceptions of mathematics in ways that broaden learners' access to the discipline. The project aims to develop informal mathematical learning experiences that make mathematics feel accessible, body-based, creative, and deeply relevant to a wide array of other knowledge domains, including both art and science. The project will build and strengthen regional and national networks of educational professionals who work in informal mathematics learning and expand the capacity of informal institutions to support engaging, innovative, content-rich, and culturally transformative mathematical learning experiences.
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TEAM MEMBERS:
Ricardo NemirovskyPaul SiboroskiMolly Kelton
COASSTal Communities of Science is a citizen-science project whose goal is to increase the scientific and educational reach of a highly successful, action-oriented and rigorous citizen science program - the Coastal Observation And Seabird Survey Team (COASST), by adding a new data module on marine debris that will feature innovative technological approaches including mobile apps and web-based crowdsourcing. The marine debris module will complement an existing module on beached birds, allowing COASST to more completely assess coastal environmental health. For instance, marine debris data, focused particularly on issues of invasive species, harm to wildlife, and debris sourcing, will be immediately useful in marine science and resource management. Once designed and vetted by professional scientists and science educators, the new module will be implemented by citizen scientists in over 100 in-community trainings conducted throughout the COASST geographic range, from northern California to the coast of Alaska, including remote coastal communities with limited access to scientific information. Over 1,000 new participants will join the program, bringing the total number of active volunteers to 2,000 within the 4 years of the project. A complementary social science research component will advance the field of informal STEM learning by focusing on the factors facilitating recruitment and especially retention in citizen science projects, using COASST as a model. The current models of science learning in informal contexts will be extended by bringing them together with conceptual approaches to the development of interest, communities of practice, and activity theory. Research will specifically focus on differences in individual motivation to join COASST; follow participants as they enter the program and eventually become central members of the COASST community of practice; and assess the degree to which individual, programmatic and socio-cultural factors contribute to participant retention. A linked independent evaluation will assess the depth of learning individuals experience as a function the training and materials they receive, and amount and type of data they collect. Both research and evaluation components will utilize pre/post surveys, interviews, and longitudinal journaling.