The art/science nexus has historically been approached through a challenge of aesthetics versus mathematics, and processes of knowledge production. Notably absent in this debate are the social sciences that explore human experience and perception. In particular, what has not been addressed clearly in the literature is how reasoning about the human experience can be provoked when people encounter content that does not assert itself as neatly defined in either an art or science discourse. By reflecting on one case study of a public art/science installation, we explore new fields of knowledge
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TEAM MEMBERS:
John FraserFiona MacDonaldNezam Ardalan
C-RISE will create a replicable, customizable model for supporting citizen engagement with scientific data and reasoning to increase community resiliency under conditions of sea level rise and storm surge. Working with NOAA partners, we will design, pilot, and deliver interactive digital learning experiences that use the best available NOAA data and tools to engage participants in the interdependence of humans and the environment, the cycles of observation and experiment that advance science knowledge, and predicted changes for sea level and storm frequency. These scientific concepts and principles will be brought to human scale through real-world planning challenges developed with our city and government partners in Portland and South Portland, Maine. Over the course of the project, thousands of citizens from nearby neighborhoods and middle school students from across Maine’s sixteen counties, will engage with scientific data and forecasts specific to Portland Harbor—Maine’s largest seaport and the second largest oil port on the east coast. Interactive learning experiences for both audiences will be delivered through GMRI’s Cohen Center for Interactive Learning—a state-of-the-art exhibit space—in the context of facilitated conversations designed to emphasize how scientific reasoning is an essential tool for addressing real and pressing community and environmental issues. The learning experiences will also be available through a public web portal, giving all area residents access to the data and forecasts. The C-RISE web portal will be available to other coastal communities with guidance for loading locally relevant NOAA data into the learning experience. An accompanying guide will support community leaders and educators to embed the interactive learning experiences effectively into community conversations around resiliency. This project is aligned with NOAA’s Education Strategic Plan 2015-2035 by forwarding environmental literacy and using emerging technologies.
The Wild Center will partner with Adirondack Museum, Cornell’s Maple Program, and New York State/Northeastern New York Maple Producers Associations to build regional identity, revitalize a heritage industry, and connect people to nature through the art, story, history, and science of maple sugaring. The Northern New York Maple Project will create interpretative exhibits with ecological, historical, and economic information. The museum will develop an instructional maple sugaring video; a touch-screen story kiosk that lets visitors share stories through the exhibit and social media; a storytelling workshop for staff, project partners, and maple producers; community events and conferences; a school education program; community sugaring workshops; and educational materials, website, social media, and outreach to industry, food enthusiasts, and the business community. Regular planning meetings on goals and deliverables will track results and an outside consultant will evaluate the overall success of the project.
This paper describes Synergies, an on-going longitudinal study and design effort, being conducted in a diverse, under-resourced community in Portland, Oregon, with the goal of measurably improving STEM learning, interest and participation by early adolescents, both in school and out of school. Authors examine how the work of this particular research-practice partnership is attempting to accommodate the six principles outlined in this issue: (1) more accurately reflect learning as a lifelong process occurring across settings, situations and time frames; (2) consider what STEM content is worth
The New Children's Museum will launch the LAByrinth project to engage the community in the creation of a permanent art installation. The museum will convene a cross-disciplinary team to design and build the LAByrinth, a climbing structure that will serve 140,000 people annually. The museum will develop relationships with underserved families and current and future museum users, and also create an ongoing community-based exhibition development process to create sustainable mechanisms for continued community involvement. The project will introduce a new socially-engaged process for creating exhibitions, which will serve as a sustainable creative catalyst for San Diego families.
The Lawrence Hall of Science will implement the "Mobile Inventor's Lab," a project to extend the benefits of an ongoing outreach program into a model that can serve visitors at a variety of locations in communities underserved by local science education organizations. The museum will refine its engineering design experiences to be easily reconfigured and delivered in a variety of locations, and develop activities and kits for library and community partner staff. This project will expand the impact of the hall's educational resources and offer audiences the opportunity to interact with and learn about engineering design experiences in their own communities.
This project will design an ambitious multi-partner, multi-format, multi-venue project focused on the Arizona-Sonora borderlands. The project combines experienced co-directors and leading borderland scholars with more than a dozen Historical and Cultural Organizations (HCOs) in small and mid-sized communities to explore and interpret the unique cultures, history, and physical landscapes of the region. The project aims to foster historical perspectives on the international border, cross-cultural understanding, and a deeper sense of place among the region’s residents and visitors. A suite of interrelated physical and digital products will elaborate five themes: the border through time; bridging cultures across borders; nature and history—ties that bind; shared identity amid social diversity; and a storied landscape. Formats include an interpretive website and digital archive; a traveling exhibit co-hosted/produced with our HCO partners; and community sponsored public programs.
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
The Exploratorium, in collaboration with the Boys and Girls Club Columbia Park (BGC) in the Mission District of San Francisco, is implementing a two-year exploratory project designed to support informal education in science, technology, engineering, and mathematics (STEM) within underserved Latino communities. Building off of and expanding on non-STEM-related efforts in a few major U.S. cities and Europe, the Exploratorium, BGC, and residents of the District will engage in a STEM exhibit and program co-development process that will physically convert metered parking spaces in front of the Club into transformative public places called "parklets." The BGC parklet will feature interactive, bilingual science and technology exhibits, programs and events targeting audiences including youth ages 8 - 17 and intergenerational families and groups primarily in the Mission District and users of the BGC. Parklet exhibits and programs will focus on STEM content related to "Observing the Urban Environment," with a focus on community sustainability. The project explores one approach to working with and engaging the public in their everyday environment with relevant STEM learning experiences. The development and evaluation processes are being positioned as a model for possible expansion throughout the city and to other cities.
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 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 Pathways Project connects rural, underserved youth and families in Eastern Washington and Northern Idaho to STEM concepts important in sustainable building design. The project is a collaboration of the Palouse Discovery Science Center (Pullman, WA), Washington State University and University of Idaho, working in partnership with rural community organizations and businesses. The deliverables include: 1) interactive exhibit prototype activities, 2) a team cooperative learning problem-solving challenge, and (3) take-home materials to encourage participants to use what they have learned to investigate ways to make their homes more energy-efficient and sustainable. The project introduces youth and families to the traditionally difficult physics concept of thermal energy, particularly as it relates to sustainable building design. Participants explore how building materials and their properties can be used to control all three types of heat transfer: conduction, convection, and radiation. The interactive exhibit prototypes are coupled with an Energy Efficient Engineering Challenge in which participants, working in cooperative learning teams, use information learned from the exhibit prototype activities to retrofit a model house, improving its energy efficiency. The project components are piloted at the Palouse Discovery Science Center, and then travel to three underserved rural/tribal communities in Northern Idaho and Eastern Washington. Front-end and formative evaluation studies will demonstrate whether this model advances participant understanding of and interest in STEM topics and careers. The project will yield information about ways that other ISE practitioners can effectively incorporate cooperative learning strategies in informal settings to improve the transferability of knowledge gained from exhibits to real-world problem-solving challenges, especially for rural and underserved audiences. This project will also provide the ISE field with: 1) a model for increasing the capacity of small, rural science centers to form collaborative regional networks that draw on previously unused resources in their communities and provide more effective outreach to the underrepresented populations they serve, and 2) a model for coupling cooperative learning with outreach exhibits, providing richer experiences of active engagement.