This book is a deliverable (requisite) of an NSF (National Science Foundation) grant to share the project outcomes and what we learned from the NSF grant project. This four-year NSF project was funded to provide professional development to museum educators about Indigenous Knowledge and Western Science in museums, with the goal of providing a culturally relevant way for Indigenous communities to connect to science. The name of this grant was “Cosmic Serpent: Bridging Native Ways of Knowing and Western Science in Museum Settings.”
This book is also a snapshot in time of this work in
The purpose of this study is to develop an instrument to assess civic scientific literacy measurement (SLiM), based on media coverage. A total of 50 multiple-choice items were developed based on the most common scientific terms appearing in media within Taiwan. These questions covered the subjects of biology (45.26%, 22 items), earth science (37.90%, 19 items), physics (11.58%, 6 items) and chemistry (5.26%, 3 items). A total of 1034 students from three distinct groups (7th graders, 10th graders, and undergraduates) were invited to participate in this study. The reliability of this instrument
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TEAM MEMBERS:
Carl-Johan RundgrenShu-Nu Chang RundgrenYuen-Hsien TsengPei-Ling LinChun-Yen Chang
This project takes an ethnographic and design-based approach to understanding how and what people learn from participation in makerspaces and explores the features of those environments that can be leveraged to better promote learning. Makerspaces are physical locations where people (often families) get together to make things. Some participants learn substantial amounts of STEM content and practices as they design, build, and iteratively refine working devices. Others, however, simply take a trial and error approach. Research explores the affordances are of these spaces for promoting learning and how to integrate technology into these spaces so that they are transformed from being makerspaces where learning happens, but inconsistently, into environments where learning is a consistent outcome of participation. One aim is to learn how to effectively design such spaces so that participants are encouraged and helped to become intentional, reflective makers rather than simply tinkerers. Research will also advance what is known about effective studio teaching and learning and advance understanding of how to support youth to help them become competent, creative, and reflective producers with technology(s). The project builds on the Studio Thinking Framework and what is known about development of meta-representational competence. The foundations of these frameworks are in Lave and Wengers communities of practice and Rogoff's, Stevens et al.'s, and Jenkins et al.'s further work on participatory cultures for social networks that revolve around production. A sociocultural approach is taken that seeks to understand the relationships between space, participants, and technologies as participants set and work toward achieving goals. Engaging more of our young population in scientific and technological thinking and learning and broadening participation in the STEM workplace are national imperatives. One way to address these imperatives is to engage the passions of young people, helping them recognize the roles STEM content and practices play in achieving their own personal goals. Maker spaces are neighborhood spaces that are arising in many urban areas that allow and promote tinkering, designing, and construction using real materials, sometimes quite sophisticated ones. Participating in designing and successfully building working devices in such spaces can promote STEM learning, confidence and competence in one's ability to solve problems, and positive attitudes towards engineering, science, and math (among other things). The goal in this project is to learn how to design these spaces and integrate learning technologies so that learning happens more consistently (along with tinkering and making) and especially so that they are accessible and inviting to those who might not normally participate in these spaces. The work of this project is happening in an urban setting and with at-risk children, and a special effort is being made to accommodate making and learning with peers. As with Computer Clubhouses, maker spaces hold potential for their participants to identify what is interesting to them at the same time their participation gives them the opportunity to express themselves, learn STEM content, and put it to use.
This project will be conducted by a team of investigators from North Carolina State University. The principal investigator proposes to examine the characteristics, motivations, in and out-of-school experiences, informal science activities, and career trajectories of 1000 science hobbyists and "master hobbyists." Master hobbyists are individuals who have developed science expertise and spend considerable free time engaging in science as a leisure activity. Master science hobbyists are found across most areas of science (e.g. birdwatchers, amateur astronomers). This research will determine who these individuals are, their career pathways, how they engage in science activities and what motivates, sustains, and defines their science interests. One of the particular goals of this research is to develop new understandings of how science hobby interests develop for women and underserved minorities. In the proposed research investigators will use the results of interviews and surveys to identify contextual factors that influence the motivational processes that, in turn, influenced choices of careers and contribute to ongoing choices in hobby and citizen science activities. Of interest in this study is how citizen scientists who are also serious hobbyists differ from master science hobbyists. Research on citizen scientists has shown that this group is highly motivated by collective motives (such as a desire to help others and further science), whereas this may not be the case with the master science hobbyist. Two groups will be sampled: a) birdwatchers and b) amateur astronomers. This sampling model will allow investigators to contrast their findings by: 1) those who have selected a science career versus those that did not select a science career, 2) those who participate in citizen science activities and those that do not, and 3) those who are birdwatchers (greater mathematical components) and those who are amateur astronomers (lesser mathematical components). Additional coding and analyses will examine any differences in the evolution of bird watching and astronomy hobbies. The results of this research will be examined in light of existing motivational and sociocultural models of career selection. This research will document differences in the perceived motivational elements that influenced master science hobbyists/citizen scientists to choose a science career or not. The results can inform federal, state, and local policies for supporting youth and adults engaged in free choice learning. Results of this research will inform the design of intervention/recruitment programs and ISE outreach initiatives. Potential audiences include ISE institutions (e.g. museums and science centers), organizations with links to STEM (e.g. scouts, boys/girls clubs) and pre- and college initiatives that seek to influence career choices and life-long science interests. The proposed cross-disciplinary approach will promote new understandings of complex issues related to motivation, retention, career selection, leisure activities, engagement with formal and informal educational environments, gender and ethnicity, communities of practice and changes in interests over time. Members of the advisory board have expertise in assessment and measurement and will work closely with the project team to conduct a detailed examination of methodologies and analyses at all phases of the project.
This pathways project will study how audiences in public spaces, in this case those in a museum setting, relate to and make sense of large data displays. The project is preliminary to development of a traveling, hands-on exhibition enabling users to create and utilize representations of big data displays such as maps and charts. As the test case, the project will use science maps that provide an overview of science generally and specific areas of STEM, charting and exploring the history and future of science and technology. The data collection portion of the project will take place at the New York Hall of Science, the Marian Koshland Science Museum, COSI in Columbus, Ohio, and WonderLab Museum in Bloomington, Indiana. The project will create a foundation for the design of museum exhibits and educational programs that teach museum visitors how to explore, engage and make better sense of big data. The project is potentially transformative because big data is becoming ubiquitous and making sense out of large data displays is necessary in order to understand big data sets.
The Adler Planetarium, Johns Hopkins University, and Southern Illinois University-Edwardsville are investigating the potential of online citizen science projects to broaden the pool of volunteers who participate in analysis and investigation of digital data and to deepen volunteers' engagement in scientific inquiry. The Investigating Audience Engagement with Citizen Science project is administering surveys and conducting case studies to identify factors that lead volunteers to engage in the astronomy-focused Galaxy Zoo project and its Zooniverse extensions. The project is (1) identifying volunteers' motivations for joining and staying involved, (2) determining factors that influence volunteers' movement from lower to higher levels of involvement, and (3) designing features that influence volunteer involvement. The project's research findings will help informal science educators and scientists refine existing citizen science programs and develop new ones that maximize volunteer engagement, improve the user experience, and build a more scientifically literate public.
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TEAM MEMBERS:
Karen CarneyMichael RaddickPamela Gay
Living Liquid will identify strategies for creating visualization tools that can actively engage the public with emerging research about the ocean's microbes and their impact on our planet. It addresses a critical issue for the ISE field: creating ways for visitors to ask and answer their own questions about emerging areas of science with visualizations. This Pathway project will provide important lessons learned for a future full-scale development project at the Exploratorium's new location over San Francisco Bay, and for informal science educators and other professionals working to create interactive visualization tools using the vast data sets now available. Living Liquid is a collaboration between developers, educators and learning researchers at the Exploratorium, computer scientists at the Visualization Interface and Design Innovation Group at UC Davis, and marine scientists at the Center for Microbial Oceanography Research and Education. The project's research and development process includes a front-end study of visitors' interests and prior knowledge related to ocean microbes, interviews with scientists to identify potential datasets and activities, a survey of candidate visualizations, and a series of prototypes to identify promising strategies to engage visitors with and allow visitors to explore large scientific datasets through visualization tools.
The Liz Lerman Dance Exchange, in partnership with several universities and a science advisory committee of distinguished international researchers in physics and astronomy, is producing "The Matter of Origins," a two-part experimental program that engages the public in explorations of the nature of beginnings and the physics of the origin of matter. Act I takes place in a theater where audiences will experience a dance performance illuminated by video and a vivid soundscape. Act II takes place in an adjacent space where audiences, who will be seated with scientists, historians, philosophers, and religious leaders, can participate in facilitated dialogue about the nature of origins in an immersive environment that incorporates dance, projected images, and provocative questions. The program will be implemented around the country, initially at four universities, with possible expansion to additional venues. The goals of this EAGER project are (1) to develop an innovative model for using dance, digital media, and structured dialogue to attract and engage public audiences in science content and processes and (2) to explore how artistic practices may have broader applications with respect to science learning and research. The intention is to explore how science can be represented in the art and in the experience and not simply interpreted into abstract choreographic expression with a program note. The program elements and outcomes will be evaluated by researchers from Michigan State University who will study impacts on the public and on participating professionals - dancers, scientists, etc. Dissemination of results will be to professional communities in the sciences, arts and informal science education.
The Oregon Museum of Science and Industry is implementing a Pathways project that will test and refine a model to promote an appreciation that science is everywhere and personally relevant by engaging transit riders in Portland, OR with location-relevant STEM content through unfacilitated, interactive science exhibits in everyday places. The study will employ a "design-based research" approach that both iteratively tests exhibit effectiveness and develops and refines an underlyting theoretical model that can contribute knowledge to the field. The "Science on the Move" model will be developed and tested using an exhibit prototype that includes 1) an easily transportable prototype core with a familiar touch-screen interface, 2) multiple sets of interactive digital content, and 3) a variety of accompanying outer skins designed to attract the public. The exhibit prototype will be placed at bus transit nodes to reach adults, specifically targeting those without college degrees who are underrepresented in science centers. A range of possible STEM content domains will be selected and tested based on topics of interest to the public. If successful, given the several challenges involved, the feasibility study will be applied more fully around Portland and be a model for other cities to consider.
The Astronomical Society of the Pacific, in collaboration with the Institute for Learning Innovation, will implement "Sharing the Universe." This research and implementation project is designed to include both a comprehensive, two-phased research component, as well as a large-scale national dissemination. The intended impacts are to improve the quality and effectiveness of informal science education activities provided by amateur astronomers; increase the frequency of public engagements in astronomy; and broaden the variety of events and diversity of the outreach to include underserved and underrepresented audiences. The project will create a community of practice using club leaders to improve astronomy clubs nationwide through research tools, training and outreach skills. Project deliverables include Phase I research which is designed to gain an understanding of how outreach-orientated clubs function and identify strategies that make successful clubs effective. Phase II will examine a core group of 20 clubs in detail to further understand the outreach culture while using interventions developed from the Phase I results such as a training DVD, Online Resource Library, Outreach Toolkit and a robust community of practice. The final deliverable will be the dissemination of proven strategies and best practices revealed by the research to 200 diverse astronomy clubs across the country. Strategic impact will be realized in increased outreach capacity among amateur astronomers and a strong model for astronomy clubs with proven best practices and resources. It is anticipated this project will reach more than 4,400 amateur astronomers and indirectly impact more than one million Americans in astronomy clubs in four years. Inverness Research will conduct the summative evaluation of the project.
This Pathways proposal seeks to find the most effective means for communicating research, research processes and ocean sciences to the public from the ocean ship Joides Resolution (JR). The JR is an NSF-supported research vessel that assists scientists and educators in their quest for understanding the science of oceans and ocean floors worldwide. The goal of this project is to find the best mechanism for communicating science through the numerous platforms of informal science education. Through a series of discussions by stakeholders that include scientists, educators, end-users in the informal science education community and evaluators, 3-5 pilot projects will be selected for further elaboration, testing and evaluation for communication methodologies. From these studies and refinements, models for communication will be produced for further implementation. Partners in this venture include: Consortium for Ocean Leadership\'s Deep Earth Academy (DEA)and the Education Division for the Integrated Ocean Drilling Program (IODP). This project will enhance the public\'s understanding of oceans, ocean floors, and related research in these elements, and inspire younger individuals who may consider ocean science as a career. Models for how best to communicate the world of ocean science will be tested and disseminated through informal science education networks and platforms. Further, models for evaluation of this multidisciplinary science endeavor will be helpful to advancing the informal science education field.
The University of California, Davis Tahoe Environmental Research Center (TERC), UC Davis W.M. Keck Center for Active Visualization in the Earth Sciences (KeckCAVES), ECHO Lake Aquarium and Science Center (ECHO), UC Berkeley Lawrence Hall of Science (LHS), and the Institute for Learning Innovation (ILI) will study how 3-D visualizations can most effectively be used to improve general public understanding of freshwater lake ecosystems and Earth science processes through the use of immersive three-dimensional (3-D) visualizations of lake and watershed processes, supplemented by tabletop science activity stations. Two iconic lakes will be the focus of this study: Lake Tahoe in California and Nevada, and Lake Champlain in Vermont and New York, with products readily transferable to other freshwater systems and education venues. The PI will aggregate and share knowledge about how to effectively utilize 3-D technologies and scientific data to support learning from immersive 3-D visualizations, and how other hands-on materials can be combined to most effectively support visitor learning about physical, biological and geochemical processes and systems. The project will be structured to iteratively test, design, and implement 3-D visualizations in both concurrent and staggered development. The public will be engaged in the science behind water quality and ecosystem health; lake formation; lake foodwebs; weather and climate; and the role and impact of people on the ecosystem. A suite of publicly available learning resources will be designed and developed on freshwater ecosystems, including immersive 3-D visualizations; portable science stations with multimedia; a facilitator's guide for docent training; and a Developer's Manual to allow future informal science education venues. Project partners are organized into five teams: 1) Content Preparation and Review: prepare and author content including writing of storyboards, narratives, and activities; 2) 3-D Scientific Visualizations: create visualization products using spatial data; 3) Science Station: plan, design, and produce hands-on materials; 4) Website and Multimedia: produce a dissemination strategy for professional and public audiences; 4) Evaluation: conduct front-end, formative, and summative evaluation of both the 3-D visualizations and science activity stations. The summative evaluation will utilize a mixed methods approach, using both qualitative and quantitative methods, and will include focus groups, semi-structured interviews, web surveys, and in-depth interviews. Leveraging 3-D tools, high-quality visual displays, hands-on activities, and multimedia resources, university-based scientists will work collaboratively with informal science education professionals to extend the project's reach and impact to an audience of 400,000 visitors, including families, youth, school field trip groups, and tourists. The project will implement, evaluate, and disseminate knowledge of how 3-D visualizations and technologies can be designed and configured to effectively support visitor engagement and learning about physical, biological and geochemical processes and systems, and will evaluate how these technologies can be transferred more broadly to other informal science venues and schools for future career and workforce development in these critical STEM areas.