Using data from interviews with 133 physicists and biologists working at elite research universities in the United States, we analyze narratives of outreach. We identify discipline-specific barriers to outreach and gender-specific rationales for commitment. Physicists view outreach as outside of the scientific role and a possible threat to reputation. Biologists assign greater value to outreach, but their perceptions of the public inhibit commitment. Finally, women are more likely than men to participate in outreach, a commitment that often results in peer-based informal sanctions. The study
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TEAM MEMBERS:
David JohnsonAnne EcklundAnne Lincoln
Scholars and pundits alike argue that U.S. scientists could do more to reach out to the general public. Yet, to date, there have been few systematic studies that examine how scientists understand the barriers that impede such outreach. Through analysis of 97 semi-structured interviews with academic biologists and physicists at top research universities in the United States, we classify the type and target audiences of scientists’ outreach activities. Finally, we explore the narratives academic scientists have about outreach and its reception in the academy, in particular what they perceive as
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TEAM MEMBERS:
Elaine Howard EcklundSarah JamesAnne Lincoln
In the Communities of Learning for Urban Environments and Science (CLUES) project, the four museums of the Philadelphia-Camden Informal Science Education Collaborative worked to build informal science education (ISE) capacity in historically underserved communities. The program offered comprehensive professional development (PD) to Apprentices from 8-11 community-based organizations (CBO), enabling them to develop and deliver hands-on family science workshops. Apprentices, in turn, trained Presenters from the CBOs to assist in delivering the workshops. Families attended CLUES events both at the museums and in their own communities. The events focused on environmental topics that are especially relevant to urban communities, including broad topics such as climate change and the energy cycle to more specific topics such as animals and habitats in urban neighborhoods.
This poster was presented at the 2014 AISL PI Meeting in Washington DC. It describes the CLUES project that provides STEM education opportunities to families.
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TEAM MEMBERS:
New Jersey Academy for Aquatic SciencesBarbara Kelly
Fifty visitors to SMM were recruited on the exhibit floor of the museum and asked to view the first draft of a seven-minute movie being developed for the Science on a Sphere exhibit. Visitors were brought into a small room, sat down and viewed the movie on a computer laptop. After watching the movie, visitors were asked a series of questions to assess their interest, enjoyment, and particular aspects of the movie. Visitors aged eight and above were eligible to be interviewed.
This poster, presented at the 2014 AISL PI Meeting, shows the impact of an afterschool program that brought hands-on, inquiry-based science to ELL students in a low SES area of Southern California. Data sources included observation of lessons, interviews with students, and collection of student work Results demonstrate a shift in student thinking around students' internalization of becoming a scientist and who is capable of being a scientist.
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TEAM MEMBERS:
University of California, IrvineLauren Shea
The Ross Sea Project was a Broader Impact projects for an NSF sponsored research mission to the Ross Sea in Antarctica. The project, which began in the summer of 2010 and ended in May 2011, consisted of several components: (1) A multidisciplinary teacher-education team that included educators, scientists, Web 2.0 technology experts and storytellers, and a photographer/writer blogging team; (2) Twenty-five middle-school and high-school earth science teachers, mostly from New Jersey but also New York and California; (3) Weeklong summer teacher institute at Liberty Science Center (LSC) where teachers and scientists met, and teachers learned about questions to be investigated and technologies to be used during the mission, and how to do the science to be conducted in Antarctica; (4) COSEE NOW interactive community website where teachers, LSC staff and other COSEE NOW members shared lesson plans or activities and discussed issues related to implementing the mission-based science in their classrooms; (5) Technological support and consultations for teachers, plus online practice sessions on the use of Web 2.0 technologies (webinars, blogs, digital storytelling, etc.); (6)Daily shipboard blog from the Ross Sea created by Chris Linder and Hugh Powell (a professional photographer/writer team) and posted on the COSEE NOW website to keep teachers and students up-to-date in real-time on science experiments, discoveries and frustrations, as well as shipboard life; (7) Live webinar calls from the Ross Sea, facilitated by Rutgers and LSC staff, where students posed questions and interacted directly with shipboard researchers and staff; and (8) A follow-up gathering of teachers and scientists near the end of the school year to debrief on the mission and preliminary findings. What resulted from this project was not only the professional development of teachers, which extended into the classroom and to students, but also the development of a relationship that teachers and students felt they had with the scientists and the science. Via personal and virtual interactions, teachers and students connected to scientists personally, while engaged in the science process in the classroom and in the field.
Native Americans exert sovereignty over vast amounts of United States land and water resources, yet are underrepresented in the disciplines that train our nation's future land and water resource managers. Native American resource managers must walk in two worlds, accommodating both traditional and modern methods that may come into conflict. Building on an existing, NSF-funded Manoomin Science Camp, the Walking Two Worlds (W2W) project will employ a systems view of resource management in considering a broad range of resource management issues affecting the region (including its lakes and wetlands, fisheries, forestry, wildlife, and air quality), with the goal of engaging the entire community in environmental and resource management issues of immediate relevance to the community. W2W will incorporate both Western science concerning the physical, chemical, and biological worlds, and traditional environmental knowledge, culture, language, and the judgment of elders. This holistic approach will not only facilitate effective resource management for the community, it will also serve as a 'hook' for engaging students and the community in STEM. A partnership of the Fond du Lac Band (of Lake Superior Chippewa) and the University of Minnesota (UMN) planned collaboratively with the community, W2W will focus on community-inspired, participatory science research projects related to resource management and environmental science. W2W will be facilitated by local teachers, with former participants as mentors, researchers and resource manages as mentors, and UMN faculty as lecturers. W2W recognizes the critical importance of strong STEM education for natural resource management. Using a mixed-methods approach to external evaluation, the project will build knowledge on the contributions of the W2W holistic, systemic approach and theme of community resource management. This will provide the foundation for a future development project that builds a community of place-based learning and community-inspired research projects.
This Advancing Informal Science Learning Pathways project, Using Technology to Research After Class (UTRAC), explores whether a combination of technology (e.g., iPad-enabled sensors, web-based inquiry-focused portal) and facilitated visits improves learning outcomes for rural and Native American elementary-age youth in after school programs. Expected outcomes include improved engagement, knowledge, skills, and attitudes toward science, technology, engineering, and math (STEM). Project goals include promoting STEM learning through science inquiry activities keyed to specific Next Generation Science Standards as well as improving how technology can be used to enhance learning outcomes in afterschool programs. The experimental design of this project - testing the effects of physical or virtual facilitation visits on learning outcomes - will lead to improvements in STEM learning outcomes among rural and underrepresented students. This project will employ several innovations in utilizing technology to teach STEM topics including: (i) hands-on, real-time, crowd sourced data collected by participants in their schoolyards; (ii) a pedagogic emphasis on communication of schoolyard data among and between participants; (iii) testing of motivational incentives; and (iv) partnerships between after school providers, preservice teachers, and university researchers as facilitators. The entire process will be modularized so that it can be modified in terms of place, STEM topic or student cohort. The topic focus of the project -- Life Under Snow -- is relevant to participating students, as Montana school playgrounds lie blanketed under snow for the majority of the school year; it includes elements of snow science, carbon cycle science, and a combination at the intersection of three recent literacy initiatives (e.g., Earth Science, Climate, or Energy). UTRAC will pilot and evaluate facilitated snow science/carbon cycle science activities that couple real-time schoolyard data with tools patterned after those available through WISE (Web-based Inquiry Science Environment; wise.berkeley.edu). Participants will collect and compare data with other youth participants, and researchers will use formative assessments to define interventions with potential to maximize student engagement and learning improvements among underserved youth. The project will advance understanding of informal education's potential to improve STEM engagement, knowledge, skills and attitudes by quantifying how - and to what extent - youth engage with emerging technologies iPad-enabled sensors, and crowdsourcing and visualization tools. The deliverables include a quantifying metric for learning outcomes, a training model for the iPad sensors and web application, an orientation kit, a social media portal, and database for the measurements.
This Partnerships for Innovation: Building Innovation Capacity (PFI:BIC) project from the University of New Hampshire focuses on a "living bridge", which exemplifies the future of smart, sustainable, user-centered transportation infrastructure. Bridges deliver such a fundamental service to society that they are often taken for granted. Typically, bridges only stir the public's interest when they must unexpectedly be replaced at great cost, or, worse, fail. The Living Bridge project will create a self-diagnosing, self-reporting "smart bridge" powered by a local renewable energy source, tidal energy, by transforming the landmark Memorial Bridge--a vertical lift bridge over the tidal Piscataqua River, with pedestrian access connecting Portsmouth, New Hampshire to Kittery, Maine--into a living laboratory for researchers, engineers, scientists, and the community at large. The Living Bridge will engage innovators in sensor and renewable energy technology by creating an incubator platform on a working bridge, from which researchers can field test and evaluate the impact and effectiveness of emerging technologies. The Living Bridge will also serve as a community platform to educate citizens about innovations occurring at the site and in the region, and about how incorporating renewable energy into bridge design can lead to a sustainable transportation infrastructure with impact far beyond the region. Sustainable, smart bridges are key elements in developing a successful infrastructure system. To advance the state of smart service systems and clean energy conversion, this project team will design and deploy a structural and environmental monitoring system that provides information for bridge condition assessment, traffic management, and environmental stewardship; advances renewable energy technology application; and excites the general public about bridge innovations. This PFI:BIC project is enabled through partnerships between academic researchers with expertise in structural, mechanical and ocean engineering, sensing technology and social science; small businesses with expertise in instrumentation, data acquisition, tidal energy conversion; and state agencies with bridge design expertise. The Living Bridge technical areas are structural health monitoring, tidal energy conversion with fluid-structure interaction measurements, estuarine environmental monitoring, and outreach communication. Sensors will be used to calibrate a three-dimensional analytical structural finite element model of the bridge. The predicted structural response from this model will assess the measured structural response of the bridge as acceptable or not. Instruments installed on the turbine deployment platform will measure the spatio-temporal structure of the turbulent inflow and modified wake flow downstream of the turbine. Resulting data will include turbine performance and loads for use in fluid-structure interaction models. Deployed environmental sensors will measure estuarine water quality; wildlife deterrent sensors will deter fish from the turbine. Hydrophones and video cameras will be used before and during turbine deployment to monitor environmental changes due to turbine presence. Outreach efforts will make bridge data, history, and information about new systems accessible and understandable to the public and K-12 educators, facilitated by an information kiosk installed at the bridge. Public awareness will be assessed with survey methods used in the N.H. Granite State Poll. The lead institution is the University of New Hampshire (UNH) with its departments of Civil Engineering, Mechanical Engineering, and Sociology, and the Center for Ocean Engineering. Primary industrial partners are a large business, MacArtney Underwater Technology Group, Inc. (Houston, TX) and two small businesses Lite Enterprises, Inc. (Nashua, NH) and Eccosolutions, LLC (New Paltz, NY.) Broader context partners are New Hampshire Department of Transportation, NH Fish & Game Department, NH Port Authority, NH Coastal Program, City of Portsmouth (NH), Sustainable Portsmouth (nonprofit), Maine Department of Transportation; U.S. Coast Guard, Archer/Western (Canton, MA, large business), Parsons-Brinkerhoff (Manchester, NH, large business), UNH Tech Camp, UNH Infrastructure and Climate Network, UNH Leitzel Center for Mathematics, Science and Engineering Education, and Massachusetts Institute of Technology's Changing Places (a joint Architecture and Media Laboratory Consortium, in Cambridge, MA).
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TEAM MEMBERS:
Erin BellTat FuMartin WosnikKenneth BaldwinLawrence Hamilton
Effective communication of science to the public by scientists is a desired and sought after attribute. This project which is working with graduate and undergraduate students in Physics will determine what interventions are best in assessing communication and attitudinal capacities in this cadre. Further, the project will determine what strategies are best at remediation. Finally, the successes will be generalized with regard to interventions and remediation to other Physics programs across the country and perhaps to other disciplines in the STEM fields. There are a variety of factors that contribute to effective communications with public audiences. Some of those factors include audience characteristics and teacher/mentor capabilities. This project will ascertain the issues in the latter teacher/mentor capacities. They will assess the mentor's baseline skills regarding communication, teaching and emergent attitudes. These are considered separately as each contributes uniquely to the effectiveness of communication. In the communications skills section, the objective will be to determine initially if the mentors are using any one of the following models: deficit, meaning the mentor is the expert and the participants are not informed; dialogue, where there is more back and forth between mentor and participant; and finally participatory interactions, where there is full integration of participant and mentor ideas. Once the baseline is established, the investigators will introduce mechanisms for remedial intervention with the student mentors to determine if and what types of changes can be made to improve communication directed toward public understanding of STEM concepts and ideas. Finally, the researchers will seek to determine if these interventions have affects beyond the immediate challenges such as career discussions, participation in classes and/or written products.
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.