Informal STEM learning experiences (ISLEs), such as participating in science, computing, and engineering clubs and camps, have been associated with the development of youth’s science, technology, engineering, and mathematics interests and career aspirations. However, research on ISLEs predominantly focuses on institutional settings such as museums and science centers, which are often discursively inaccessible to youth who identify with minoritized demographic groups. Using latent class analysis, we identify five general profiles (i.e., classes) of childhood participation in ISLEs from data
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TEAM MEMBERS:
Remy DouHeidi CianZahra HazariPhilip SadlerGerhard Sonnert
The project team published a research synopsis article with Futurum Science Careers in Feb 2023 called “How Can Place Attachment Improve Scientific Literacy?”
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 RASOR project is designed to increase engagement of students from rural Alaska communities in biomedical/STEM careers. Rural Alaskan communities are home to students of intersecting identities underrepresented in biomedical science, including Alaska Native, low-income, first generation college, and rural. Geographic isolation defines these communities and can limit the exposure of students to scientifically-minded peers, professional role models, and science career pathways. However these students also have a particularly strong environmental connection through subsistence and recreational activities, which makes the one-health approach to bio-medicine an intuitive and effective route for introducing scientific research and STEM content. In RASOR, we will implement place-based mentored research projects with students in rural Alaskan communities at the high school level, when most students are beginning to seriously consider career paths. The biomedical one-health approach will build connections between student experiences of village life in rural Alaska and biomedical research. Engaging undergraduate students in research has proved one of the most successful means of increasing the persistence of minority students in science (Kuh 2008). Furthermore, RASOR will integrate high school students into community-based participatory research (Israel et al. 2005). This approach is designed to demonstrate the practicality of scientific research, that science has the ability to support community and cultural priorities and to provide career pathways for individual community members. The one-health approach will provide continuity with BLaST, an NIH-funded BUILD program that provides undergraduate biomedical students with guidance and support. RASOR will work closely with BLaST, implementing among younger (pre-BLaST) students approaches that have been successful for retaining rural Alaska students along STEM pathways and tracking of post-RASOR students. Alaska Native and rural Alaska students are a unique and diverse population underrepresented in biomedical science and STEM fields.
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TEAM MEMBERS:
Janice StraleyEllen Chenowith
resourceresearchPark, Outdoor, and Garden Programs
There is growing concern that opportunities for outdoor learning by school students in England have decreased substantially in recent years. In response to this, and recent Government calls for ‘schools to make better use of the outdoor classroom as a context for teaching and learning’, the Field Studies Council (FSC) and several partner organisations commissioned the National Foundation for Educational Research (NFER) to undertake a review of research on outdoor learning.
This document summarises the key findings of this review, which critically examined 150 pieces of research on outdoor
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TEAM MEMBERS:
Mark RickinsonJustin DillonKelly TeameyMarian MorrisMee Young ChoiDawn SandersPauline Benefield
resourceresearchGames, Simulations, and Interactives
We describe a game and teachers’ experiences using it in their middle and high school science courses. The game, which is called “Luck of the Draw,” was designed to engage middle, high school, and college students in genetics and encourage critical thinking about issues, such as genetic engineering. We introduced the game to high school science teachers attending a summer workshop and asked them to describe their initial impressions of the game and how they might use it in their classes; later, during the academic year, we asked them whether they used the game in their classrooms and, if so
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TEAM MEMBERS:
Alicia BowerKami L. TsaiCarey S. RyanRebecca AndersonAndrew JametonMaurice Godfrey
Charles Darwin is largely unknown and poorly understood as a historical figure. Similarly, the fundamental principles of evolution are often miss-stated, misunderstood, or entirely rejected by large numbers of Americans. Simply trying to communicate more facts about Darwin, or facts supporting the principles of evolution is inadequate; neither students nor members of the public will care or retain the information. On the contrary, building facts into a one-on-one conversational narrative creates an memorable opportunity to learn. Here, we create a digital-media, self-guided question and answer
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TEAM MEMBERS:
David J. LampeBrinley KantorskiJohn Pollock
Lack of diversity in science and engineering education has contributed to significant inequality in a workforce that is responsible for addressing today's grand challenges. Broadening participation in these fields will promote the progress of science and advance national health, prosperity and welfare, as well as secure the national defense; however, students from underrepresented groups, including women, report different experiences than the majority of students, even within the same fields. These distinctions are not caused by the students' ability, but rather by insufficient aspiration, confidence, mentorship, instructional methods, and connection and relevance to their cultural identity. The long-term vision of this project is to amplify the impact of a successful broadening participation model at the University of Maine, the Stormwater Research Management Team (SMART). This program trains students and mentors in using science and engineering skills and technology to research water quality in their local watershed. Students engage in numerous science and technology fields: engineering design, data acquisition, analysis and visualization, chemistry, environmental science, biology, and information technology. Students also connect with a diversity of professionals in water and engineering in government, private firms and non-profits. SMART has augmented the traditional science and engineering classroom by engaging students in guided mentored apprenticeships that address community problems.
Technical
This pilot project will form a collaborative and define a strategic plan for scale-up to a national alliance to increase the long-term success rate of underrepresented minority students in science, engineering, and related fields. The collaborative of multiple and varied organizations will align to collectively contribute time and resources to a pre-college educational pathway. There are countless isolated programs that offer short-term interventions for underrepresented and minority students; however, there is lack of organizational coordination for aligning current program offerings, sharing best practices, research results or program outcomes along the education to workforce pathway. The collaborative activities will focus on the transition grades (e.g., 4-5, 8, and high school) and emphasize relationships among skills, confidence, culture and future careers. Collaborative partners will establish a centralized infrastructure in each location to coordinate recruiting of invested community leaders, educators, and parents, around a common agenda by designing, deploying and continually assessing a stormwater-themed project that addresses their location and demographic specific needs. This collaborative community will consist of higher education faculty and students, K-12 students, their caregivers, mentors, educators, stormwater districts, state and national environmental protection agencies, departments of education, and other for-profit and non-profit organizations. The collaborative will address the need for research on mechanisms for change, collaboration, and negotiation regarding the greater participation of under-represented groups in the science and technology workforce.
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TEAM MEMBERS:
Mohamed MusaviVenkat BhethanabotlaCary JamesVemitra WhiteLola Brown
A non-technical description of the project test explains its significance and importance.
The goal of this project is to help students easily identify themselves as science or engineering professionals and increase the proportion of the local population, dominantly minorities, who pursue science and technology careers. Experience has demonstrated that students are most engaged in technical fields when they can participate in active, hands-on learning around problems with application to their local community. The focus of the effort is in marine science, which has local relevance to both the environment and the economy of the U.S. Virgin Islands. The project will use interventions at three crucial stages: middle school, high-school-college transition, and master-PhD transition, to engage students with specific active-learning and research-oriented programs. Community partners comprise a wide-ranging local organization that leverages the resources of other successful collaborations.
A technical description of the project
This project will create a transferable model that uses innovative partnerships among universities, governmental and non-governmental organizations, a professional society, and businesses, to create a local backbone organization with a shared vision for change and common success metrics broaden participation in science, technology, engineering, and mathematics (STEM). This project addresses the critical challenge of building scientific identity to increase interest and engagement of underrepresented minorities in STEM fields in the U.S. Virgin Islands. The plan includes targeted interventions at three significant times in the student career pathway (middle/high school, early college, and graduate school) that comprise: (1) field experiences in the marine sciences for middle/high school students, (2) early field research experiences for college freshmen and sophomore students, (3) bridge programming to a Ph.D. partnership with Pennsylvania State University, and (4) an intensive mentoring program. The model is grounded in social innovation theory through a framework that meets the five conditions for collective impact: common agenda, shared measurement of data and results, mutually reinforcing activities, continuous communication, and backbone support.
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TEAM MEMBERS:
Kristin Wilson GrimesMarilyn BrandtNastassia JonesCarrie BucklinMonica Medina
Brazilian research has grown intensely in all areas of microbiology, with the increase in the amount of governmental resources for the sector and the strengthening of a greater number of research groups. However, very few academic studies deal with research about teaching and science communication in microbiology. There is no in-depth study of how this topic is currently being divulgated in communication journals, didactic books and the Internet, or about the interest and the difficulties faced by researchers in communicating microbiology to the general public. This paper investigates academic
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TEAM MEMBERS:
Daniela Franco Carvalho JacobucciGiuliano Buza Jacobucci
At the end of the dark ages, anatomy was taught as though everything that could be known was known. Scholars learned about what had been discovered rather than how to make discoveries. This was true even though the body (and the rest of biology) was very poorly understood. The renaissance eventually brought a revolution in how scholars (and graduate students) were trained and worked. This revolution never occurred in K–12 or university education such that we now teach young students in much the way that scholars were taught in the dark ages, we teach them what is already known rather than the
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TEAM MEMBERS:
Robert DunnJulie UrbanDarlene CavalierCaren Cooper