The project team published a research synopsis article with Futurum Science Careers in Feb 2023 called “How Can Place Attachment Improve Scientific Literacy?”
The Fairchild Tropical Botanic Garden will conduct the Million Orchid Project Authentic STEM Initiative to provide inclusive and accessible STEM learning opportunities for approximately 1,800 students annually from the most diverse and under-resourced middle and K-8 schools in Miami–Dade County. The initiative will use the Fairchild's STEMLab — a mobile plant propagation lab designed especially for schoolchildren — to bring the museum’s specialized scientific research to young learners in South Florida neighborhoods. Students and teachers will collect and analyze scientific data, devise research questions, and test hypotheses that will advance local conservation and contribute to the propagation of endangered orchids. Students will have the opportunity to explore STEM careers through interactions with Fairchild botanists.
The Arizona-Sonora Desert Museum will partner with the Flowing Wells Unified School District on “We Bee Scientists,” a program to engage students in grades K–6 in real-world science by learning about bees—the most important group of pollinators. They plan to create a curriculum and related activities aligned with the Arizona science standards. The program is an expansion of the Tucson Bee Collaborative, which empowers community scientists from “K to grey” to contribute to ecosystem health and understanding through the study of native bees. The museum also will partner with Pima Community College and the University of Arizona on the program, which will involve volunteers and high school, college, and university students in documenting the abundance and diversity of native bees.
Science identity has been shown to be a necessary precondition to academic success and persistence in science trajectories. Further, science identities are formed, in large part, due to the kinds of access, real or perceived, that (racialized) learners have to science spaces. For Black and Latinx youth, in particular, mainstream ideas of science as a discipline and as a culture in the US recognize and support certain learners and marginalize others. Without developing identities as learners who can do science, or can become future scientists, these young people are not likely to pursue careers in any scientific field. There are demonstrable links between positive science identities and the material and social resources provided by particular places. Thus, whether young people can see themselves as scientists, or even feel that they have access to science practices, also depends on where they are learning it. The overarching goal of this project is to broaden participation of Black and Latinx youth in science by deepening our understanding of both science identities and how science learning spaces may be better designed to support the development of positive science identities of these learners. By deepening the field’s knowledge of how science learning spaces shape science identities, science educators can design more equitable learning spaces that leverage the spatial aspects of program location, culturally relevant curriculum, and participants’ lived experiences. A more expansive understanding of positive science identities allows educators to recognize these in Black and Latinx learners, and direct their continued science engagements accordingly, as positive identities lead to greater persistence in science. This project is a collaboration between researchers at New York University and those at a New York City informal science organization, BioBus. It is funded by the Advancing Informal STEM Learning (AISL) Program which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments.
This participatory design research project will compare three different formats, in different settings, of afterschool science programming for middle schoolers: one located in a lab space on the campus of a nearby university, one located in the public middle school building of participating students, and one aboard a mobile science lab. For purposes of this study, the construct of “setting” refers to the dimensions of geographic location, built physical environment, and material resources. Setting is not static, but instead social and relational: it is dynamically (co)constructed and experienced in activity by individuals and in interaction by groups of individuals. Therefore, the three BioBus programming types allow for productive comparison not only because of their different geographic locations, built environments, and material resources (e.g., scientific tools), but also the existing relationships learners may have with these places, as well as the instructional designs and pedagogical practices that BioBus teaching scientists use in each. This project uses a design-based research approach to answer the following research questions: (1) How do the settings of science learning shape science identity development? What are different positive science identities that may emerge from these relationships? And (2) What are ways to leverage different spatial aspects of informal science programming and instruction to support positive science identities? The study uses ethnographic and micro-analytic methods to develop better understandings of the relationships between setting and science identity development, uncover a broad range of types of positive science identities taken up by our Black and Latinx students, and inform informal science education to design for and leverage spatial aspects of programming and instruction. Findings will contribute to a systematic knowledge base bringing together spatial aspects of informal science education and science identity and identity development, and provide new tools for informal science educators, including design principles for incorporating spatial factors into program and lesson planning.
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TEAM MEMBERS:
Jasmine MaLatasha WrightRoya Heydari
The Cincinnati Museum Center will develop a permanent exhibition to showcase its invertebrate paleontology collection and develop related educational programming that builds on a strong commitment to gender equity. Using focus groups, prototypes, surveys, and feedback from existing programs, the museum will incorporate community input from key audiences into the design of the 4,800 square-foot immersive gallery, which will blend science, history, and technology. The museum will engage external designers to create schematic and final exhibit designs. The museum will develop and test related educational programs for families and students, with a special focus on engaging girls ages 7 to 14 in STEM activities.
The Museum of Science in Boston, Massachusetts is one of the world’s largest science centers and the most visited cultural institution in New England. Located in Science Park, a piece of land that spans the Charles River, the museum is conveniently situated close to Boston and Cambridge. The museum has more than 700 interactive exhibits and a number of live presentations offered daily. One of these daily shows include live animal presentations, where museum visitors can learn more about some of the many animals that the museum cares for in its live animal center. An evaluation of these live
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TEAM MEMBERS:
Sarah RosenthalKristina OhlSadia Sehrish IslamMaría José Brito Páez
Two critical challenges in science education are how to engage students in the practices of science and how to develop and sustain interest. The goal of this study was to examine the extent to which high school youth, the majority of whom are members of racial and ethnic groups historically underrepresented in STEM, learn the skills and practices of science and in turn develop interest in conducting scientific research as part of their career pursuits. To accomplish this goal, we applied Hidi and Renninger’s well-tested theoretical framework for studying interest development in the context of
This is an NSF Postdoctoral Research Fellowship in Biology, under the program Broadening Participation of Groups Under-represented in Biology. The fellow, Robert Habig, is conducting research and receiving training that is increasing the participation of groups underrepresented in biology. The fellow is being mentored by David Lahti at Queens College, City University of New York. The goal of the fellow's project is to perform a comparative evolutionary analysis of nest construction in the weaverbirds (Ploceus spp.). The evolutionary history of behavior can be nearly intractable and resistant to quantitative analysis. One strategy for illuminating our understanding of behavioral evolution is to conduct comparative studies of animal architectures, such as nests. Unlike behaviors themselves, nests persist through time, and have structures that can be disassociated into several quantitative features, which permits easy and comparable measurements and allows scientists to address questions about evolutionary history and functional relevance. The fellow's research addresses two major questions: (1) How do patterns of nest construction vary within and between species? (2) How do interrelated evolutionary processes shape variation in nest structure? This project is important for advancing foundational scientific knowledge, and will be the first study of weavers incorporating both molecular data and nest morphology to better understand the evolutionary underpinnings of a complex behavioral process. The fellow is also broadening participation in science by mentoring students underrepresented in biology.
The Fellow will reconstruct the evolution of nest construction in Ploceus weaverbirds incorporating advanced phylogenetic and morphological techniques including bioinformatics, computer modeling, X-ray computed tomography, and image processing. The Fellow will also conduct fieldwork in two hotspots of weaverbird diversity, the Awash Valley in Ethiopia and the Limpopo Province of South Africa, and collect behavioral data (e.g. rates of predation and brood parasitism; mating and parental behavior) and morphological data (e.g. nest structure) to test hypotheses of how distinct types of evolutionary selection shape the evolution of nest construction. The proposed comparative study can thus address questions such as how rapidly certain nest structural features evolve, which features are ancestral versus derived, which tend to exhibit phylogenetic signal, and which evolve in response to environmental features. The Fellow is receiving training in three-dimensional morphological analyses, phylogenetic tree construction, bioinformatics, computer modeling, and mentoring skills. The plan to broaden participation includes (1) recruitment, training, and mentoring of Queens College students from underrepresented groups in biology; (2) designing an evolutionary biology curriculum that ties in the research of the fellowship; (3) teaching an evolutionary biology class to underrepresented middle and high school students at the American Museum of Natural History; and (4) facilitating a research team for middle school and high school students.
This presentation "Revealing Impacts: How does one long-term, statewide field trip program influence a community's learning ecosystem?" was shared as showcase at the 2021 Connected Learning Summit (https://app.clowdr.org/conference/clsummit2021/) held virtually from July 7-30, 2021.
In the showcase session, we shared details of an NSF funded collaborative project between the Gulf of Maine Research Institute, Oregon State University and TERC to understand how a longstanding, statewide field trip program, LabVenture, influences a community’s learning ecosystem. The project uses the construct
Our goal in creating this guide is to provide practitioners, organizations, researchers, and others with a “one-stop shop” for measuring nature connections. The guide is for those interested in assessing and enhancing the connections their audiences have to nature; we use the term “audience” to refer broadly to your participants or to any group you are trying to assess. The guide can help you choose an appropriate tool (for example, a survey or activity) for your needs, whether you work with young children, teenagers, or adults (see the Decision Tree on p. 14). The guide also includes 11 tools
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TEAM MEMBERS:
Gabby SalazarKristen KunkleMartha Monroe
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative research, approaches, and resources for use in a variety of settings.
This RAPID was submitted in response to the NSF Dear Colleague letter related to the COVID-19 pandemic. This award is made by the AISL program in the Division of Research on Learning, using funds from the Coronavirus Aid, Relief, and Economic Security (CARES) Act. The project will develop and research an integrated package of high-quality, widely accessible media and other outreach materials designed to engage middle school youth, educators, and libraries in learning about viruses in relation to COVID-19. There is an immediate need to provide youth with accurate, engaging, and accessible materials to help them understand the basic biology underlying the COVID-19 pandemic, including the routes of COVID-19 transmission and mechanisms to prevent its spread. This is particularly important for those without science backgrounds or interests so that the rumors, hearsay, and gossip circulating among youth can be replaced with research-based information. Since 2007, the project team and partners have focused on developing and studying new ways of educating youth and the public about biology, virology, and infectious disease. The project will develop a web-accessible package of customizable graphics, illustrated stories, and essays--all of which can be easily incorporated into free-choice and directed on-line learning as well standards-based lesson plans for Grades 6-8. These resources will be disseminated broadly and at no cost to youth and educators of all kinds, including schools, libraries, museums, and other established networks for formal and informal science education. The project web package will be linked to multiple websites that serve as important educational resources on science and virology for youth, the general public, and educators. A prominent university press will publish and promote the illustrated stories and support distribution of 7,000 free copies.
The project will conduct research examining how richly-illustrated science narratives impact youth understanding of and curiosity about science. The research will help develop the foundation for better understanding how to educate youth about COVID-19 (and future pandemics) while generating new knowledge about effective methods for public science outreach during a major unanticipated natural event. For formative evaluation, the project will use an innovative rapid response feedback method. Youth will be invited to provide timely, specific comments on the serialized stories through a curated portal. As new excerpts are related online, different questions will be posed to youth who are selected because of specific characteristics (e.g., low or high initial science interest). These data will guide story development in real time and provide a mechanism to gauge the story appeal, comprehensibility, and initial impacts. The project will address two research questions: (1) How effective are illustrated stories in having positive impacts among participants on COVID-19 knowledge, science identity, attitudes, and interest in science careers?; and (2) How do story lines and characters have differential impacts on virus knowledge, epidemiology, and youth attitudes towards science and science careers? To conduct this research, the project will conduct online surveys using adapted items from prior research conducted by the project team. Additional items will assess COVID-19 knowledge, attitudes, personal experiences with the virus, well-being, and exposure to public health messaging about the virus. Research findings will be shared widely to inform the field about new ways delivering science education content during the advent of rapidly evolving global and educational challenges.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
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TEAM MEMBERS:
Judy DiamondJulia McQuillanPatricia Wonch HillElizabeth VanWormer
Growing Beyond Earth (GBE) is Fairchild’s NASA-funded classroom science project designed to advance research on growing plants aboard spacecraft. As NASA looks toward a long term human presence beyond Earth orbit, there are specific science, technology, engineering, and math (STEM) challenges related to food production. GBE is addressing those challenges by expanding the diversity and quality of edible plants that can be grown in space. On Earth, GBE is also improving technologies for gardening in urban, indoor, and other resource-limited settings.
GBE is unique in its focus on real
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TEAM MEMBERS:
Marion LitzingerCatherine RaymondCarl LewisAmy Padolf