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
National Foundation for the Blind (NFB) Engineering Quotient (EQ) for Teachers is a free, online curriculum and collection of resources for educators who want to teach NFB EQ, the National Federation of the Blind’s week-long engineering program designed for blind and low-vision youth.
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TEAM MEMBERS:
Natalie ShaheenWade GoodridgeSarah LopezPeter AndersonAnn CunninghamDavid Nietfeld
This guidebook will help you plan your action project. The initial brainstorm pages will help you consider where to start, and the Action Project Framework will navigate you through steps to get to your destination: the completion of your project!
This project focuses on environmental health literacy and will explore the extent to which diverse rural and urban youth in an out-of-school STEM enrichment program exhibit gains in environmental health literacy while engaged in learning and teaching others about community resilience in the face of changing climates. Science centers and museums provide unique opportunities for youth to learn about resilience, because they bring community members together to examine the ways that current science influences local decisions. In this project, teams of participating youth will progress through four learning modules that explore the impacts of changing climates on local communities, the local vulnerabilities and risks associated with those changes, possible mitigation and adaptation strategies, and building capacities for communities to become climate resilient. After completion of these modules, participating youth will conduct a resilience-focused action project. Participants will be encouraged to engage peers, families, friends, and other community stakeholders in the design and implementation of their projects, and they will gain experience in accessing local climate and weather data, and in sharing their findings through relevant web portals. Participants will also use various sensors and web-based tools to collect their own data.
This study is guided by three research questions: 1) To what extent do youth develop knowledge, skills, and self- efficacy for developing community resilience (taken together, environmental health literacy in the context of resilience) through participation in museum-led, resilience-focused programming? 2) What program features and settings foster these science learning outcomes? And 3) How does environmental health literacy differ among rural and urban youth, and what do any differences imply for project replication? Over a two- year period, the project will proceed in six stages: a) Materials Development during the first year, b) Recruitment and selection of youth participants, c) Summer institute (six days), d) Workshops and field experiences during the school year following the summer institute, e) Locally relevant action projects, and f) End- of-program summit (one day). In pursuing answers to the research questions, a variety of data sources will be used, including transcripts from youth focus groups and educator interviews, brief researcher reflections of each focus group and interview, and a survey of resilience- related knowledge. Quantitative data sources will include a demographic survey and responses to a self-efficacy instrument for adolescents. The project will directly engage 32 youth, together with one parent or guardian per youth. The study will explore the experiences of rural and urban youth of high school age engaged in interactive, parallel programming to enable the project team to compare and contrast changes in environmental health literacy between rural and urban participants. It is anticipated that this research will advance knowledge of how engagement of diverse youth in informal learning environments influences understanding of resilience and development of environmental health literacy, and it will provide insights into the role of partnerships between research universities and informal science centers in focusing on community resilience.
Supporting more equitable participation in science, technology, engineering, and mathematics (STEM) remains a key, persistent educational challenge. This paper employs a sociological Bourdieusian lens to explore how equitable youth outcomes might be supported through informal science learning (ISL). Drawing on multimodal, ethnographic data from four case study youth aged 11–14 from two ISL programs, we identify four areas of practice that were enacted to a greater or lesser extent in the programs in support of equitable youth outcomes. We identify how the equitable potential of these practices
Many youth programs seek to understand their influence over time on participant outcomes. This paper offers a methodology for measuring a participant’s perception of a program’s contribution amid their perception of other youth influences such as those from family, school, peer groups, hobbies, and other organized activities. The instrument built on the large body of work on youth influences in order to capture the dominant factors in development of the item bank. In addition to item development, the paper documents face validity followed by content assessment of items using a research panel
This poster was presented at the 2021 NSF AISL Awardee Meeting.
This project is a retrospective study to explore the long-term impact of STEM programming. The study follows up with participants to ask questions like "Where are they now? What mattered? What difference did it make? and What’s next?"
Background: Authentic research experiences and mentoring have positive impacts on fostering STEM engagement among youth from backgrounds underrepresented in STEM. Programs applying an experiential learning approach often incorporate one or both of these elements, however, there is little research on how these factors impact youth’s STEM engagement during the high school to college transition. Purpose: Using a longitudinal design, this study explored the impact of a hands-on field research experience and mentoring as unique factors impacting STEM-related outcomes among underrepresented youth
Science is a process of inquiry that involves question asking, experimentation, and exploration. However, for youth, it is often presented as settled, a fixed collection of facts, principles, and theories that can seem sterile and unimaginative. This project is designed to combat that idea. This Research in Service to Practice project brings scientists, middle school youth and choreographers together to explore unsettled scientific phenomena from a complex systems perspective using choreography and agent-based modeling (ABM), to engage all participants in cutting edge scientific inquiry. Given the ubiquity of complex systems, being able to adopt a complex systems perspective is critical to understanding the world and our relationship to it. However, research has shown that this can be a challenge, specifically for youth. While most complex systems research has not focused on the role of the body, recent studies have shown the promise and potential of embodiment as its own form of reasoning about complex systems. Thus, this project will create exploratory science spaces foregrounding embodiment in the process of scientific discovery. The program has two phases: (1) a 20-hour training workshop where scientists and choreographers engage in interdisciplinary collaborative design work, and (2) a 60-hour summer program where the researcher-practitioner partnership involving scientists, choreographers and youth engages in agent- based & embodied choreographic scientific modeling. The summer program takes place in community-based centers in Gainesville, FL and Boston, MA broadening perceptions of what science research looks like and can be. Each site will host 20 youth, two local scientists, and a local choreographer. Participants will engage in embodied collaborative inquiry, brainstorming and modeling to create choreographic representations and culminate in a public event for the community. The project aims to understand the experiences of and shifts in youth and scientists as they engage in these activities and to understand how to design such a model for informal learning. The project will also help scientists apply a complex systems lens to their own work and settled perspectives. This project 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.
Using a design-based research (DBR) approach, the project will develop and expand embodied and agent-based learning theories, while also piloting, analyzing, and refining collaborative models for science learning in informal spaces. The research questions are: 1. How does engaging in the process of creating embodied and agent-based models of complex systems contribute to new ways of understanding science, de-settle ideas about the process of how science gets “made”, and impact understanding of the role of the body in making science? and 2. How can arrangements of bodies and modeling tools work together to support understanding of complex systems? The research and design are informed by three main theoretical principles: (a) science is “dance of agency”, a process of inquiry that through iterative dialogic interaction with tools, technology, and humans, produces understandings that more and more closely explain natural phenomena; (b) embodied-interactionist theories of learning allow us to understand representational sense-making by looking closely at the processes by which representations are made, not just at representational end- products; and (c) creative embodiment and agent based modeling are valuable tools for sense-making around complex science ideas and emergent phenomena. Two cycles of design, implementation, and analysis across two different informal learning sites will be conducted. Data will be collected at both sites, resulting in four implementation and data collection periods. Each round of implementation will be staggered so that reflections and lessons from an implementation can inform the next design iteration. This project will provide insights on the relationship between choreography and ABM as tools for scientific sense-making and expand ABM to consider the role of movement and bodies more broadly in physical space. It will also contribute to an understanding of how underrepresented youth’s perceptions and conceptions of science can be shaped through embodied science activities, and of the relationships these youth see between their own bodies and identities, science, and the creative arts. Finally, by involving individuals from underrepresented communities as researchers, designers, scientists, evaluators, and advisors, this project expands cross-cultural and training opportunities within the field of education and STEM research.
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TEAM MEMBERS:
Dionne ChampionAditi WaghLauren Vogelstein
Research suggests that when both science, technology, engineering, and mathematics (STEM) education and social-emotional development (SED) are supported in afterschool, summer, and other informal settings, young people can better develop skills for the future such as leadership, decision-making, and relationship-building so they could have successful careers/participation in STEM. However, researchers and practitioners working in the out-of-school time (OST) sector often do so without connections across these fields. The appeal for more integration of STEM and SED in OST program delivery and data collection has remained abstract and aspirational. This Literature Review and Synthesis project is the next step needed to move the OST field toward the intentional, explicit, and evidence-based integration of STEM and SED in research and practice. The project will create shared understanding necessary to improve program content, staff training, and evaluation. This synthesis will support future research on unified STEM+SED that can lead to more effective, equitable, and developmentally appropriate programming. Improved programming will contribute to talent development, address STEM workforce needs, and promote socioeconomic mobility to benefit children, youth, educators, and society. This project 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 project will systematically examine what domains and skills at the interface of STEM+SED are most researched among K-12 youth in informal STEM learning environments, compared to formal STEM educational environments. The team will further explore how gender, race, and other intersectional forms of equity can be added to the STEM+SED equation. The project team will search and appraise empirical and gray literature (2001-2020) to identify the most commonly researched domains and skills at the interface of STEM+SED in informal environments serving K-12 youth. The review and synthesis process will include four steps: search, appraisal, synthesis, and analysis. The search will begin with STEM+SED skills in four foundational domains (agency, belonging, engagement, and reflection) identified previously with experts from the fields of STEM and SED. The search will include all existing, eligible references from formal K-12 settings to contrast commonly studied domains and skills (e.g., perseverance, self-regulation, teamwork, complex problem-solving, self-awareness) in formal versus informal learning environments. The study approach will then compare these domains and skills by the demographics variables noted above. Following the creation of a strong catalog of evidence, information will be synthesized using three “pillars” for building coherence in STEM+SED integration: phenomenon (the knowing), implementation (the doing) and assessment (the result). These pillars will be used to organize and critically analyze the literature. Building conceptual coherence through a systematic review and synthesis of literature from the fields of STEM and SED will lead to greater understanding of STEM+SED in OST practice, highlight the most important content and skills to learn in informal environments, and identify when and how youth should learn specific content and skills at the interface of STEM+SED. Applying coherence to the integration of STEM+SED ensures that the principles and practices are layered carefully, in ways that avoid superficial checklists or duplication of effort and build meaningfully upon young people’s knowledge and skills. The long-term goal is to broker connections and alignment of STEM+SED across schools and OST programs. Recommendations and a roadmap to guide equitable, effective STEM+SED research, practice, and policy will result from this research.
In this paper, we examine the relationship between participants’ childhood science, technology, engineering, and mathematics (STEM) related experiences, their STEM identity (i.e., seeing oneself as a STEM person), and their college career intentions. Whereas some evidence supports the importance of childhood (i.e., K‐4) informal STEM education experiences, like participating in science camps, existing research does not adequately address their relationship to STEM career intention later in life. Grounding our work in identity research, we tested the predictive power of STEM identity on career
Computing fields are foundational to most STEM disciplines and the only STEM discipline to show a consistent decline in women's representation since 1990, making it an important field for STEM educators to study. The explanation for the underrepresentation of women and girls in computing is twofold: a sense that they do not fit within the stereotypes associated with computing and a lack of access to computer games and technologies beginning at an early age (Richard, 2016).
Informal coding education programs are uniquely situated to counter these hurdles because they can offer additional