This is a brief literature review examining the theory and practice of Community-Based Participatory Research (CBPR). It highlights CBPR's liberatory intent, and focuses on CBPR practice in indigenous communities and among youth.
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
Milwaukee has established itself as a leader in water management and technology, hosting a widely recognized cluster of industrial, governmental, nonprofit, and academic activity focused on freshwater. At the same time, Milwaukee faces a wide range of challenges with freshwater, some unique to the region and others common to cities throughout the country. These challenges include vulnerability to flooding and combined sewer overflows after heavy rainfall, biological and pharmaceutical contamination in surface water, lead in drinking water infrastructure, and inequity in access to beaches and other recreational water amenities. Like other cities, Milwaukee grapples with the challenges global climate change imposes on urban water systems, including changing patterns of precipitation and drought.
These problems are further complicated by Milwaukee's acute racial and economic residential segregation. With a population of approximately 595,000, embedded within a metropolitan area of over 1.5 million, Milwaukee remains one of the country's most segregated cities. There is increasing urgency to engage the public--and especially those who are most vulnerable to environmental impacts--more deeply in the stewardship of urban water and in the task of creating sustainable urban futures. The primary goal of this four-year project is to foster community-engaged learning and environmental stewardship by developing a framework that integrates art with Science, Technology, Engineering, and Mathematics (STEM) experiences along with geography, water management, and social science. Synergies between STEM learning and the arts suggest that collaborations among artists, scientists, and communities can open ways to bring informal learning about the science of sustainability to communities.
WaterMarks provides an artist generated conceptual framework developed by Mary Miss / City as Living Laboratory (CALL) to help people better understand their relationship to the water systems and infrastructure that support their lives. Project activities include artist/scientist/community member-led Walks, which are designed to engage intergenerational participants both from the neighborhoods and from across the city, in considering the conditions, characteristics, histories, and ecosystems of neighborhoods. Walks are expanded upon in Workshops with residents, local scientists/experts, and other stakeholders, and include exploring current water-related environmental challenges and proposing solutions. The Workshops draw on diverse perspectives, including lived experience, scientific knowledge, and policy expertise. Art projects created by local artists amplify community engagement with the topics, including programming for teens and young adults. Free Wi-Fi will be integrated into various Marker sites around the city providing access to online, self-guided learning opportunities exploring the water systems and issues facing surrounding neighborhoods. Current programming focuses primarily on Milwaukee's predominantly African American near North Side and the predominantly Latinx/Hispanic near South Side. Many neighborhoods in these sections are vulnerable to such problems as frequent flooding, lead contamination in drinking water, inequities in safety and maintenance of green space, and less access to Lake Michigan, the city's primary natural resource and recreational amenity.
The WaterMarks project advances informal STEM learning in at least two ways. First, while the WaterMarks project is designed to fit Milwaukee, the project includes the development of an Adaptable Model Guide. The Guide is designed so that other cities can modify and employ its inclusive structure, programming, and process of collaboration among artists, scientists, partner organizations, and residents to promote citywide civic engagement in urban sustainability through the combination of informal STEM learning and public art. The Guide will be developed by a Community-University Working Group (CULab) hosted by UW-Milwaukee's Center for Community-Based Learning, Leadership, and Research and made up of diverse community and campus-wide stakeholders. In addition to overseeing the Guide’s creation, CULab will conceptualize onboarding and mentorship strategies for new participants as well as a framework for the program’s expansion and sustainability.
Second, through evaluation and research, the project will build a theoretical model for the relationships among science learning, engagement with the arts, and the distinctive contexts of different neighborhoods within an urban social-ecological system. The evaluation team, COSI’s Center for Research and Evaluation, and led by Co-PI Donnelly Hayde, aims to conduct formative, summative, and process evaluation of the Watermarks project, with the additional goal of producing evaluative research findings that can contribute to the broader field of informal learning. Evaluation foci include: How does the implementation of WaterMarks support positive outcomes for the project’s communities and the development of an adaptable model for city-scale informal science learning about urban environments? 2. To what extent do the type and degree of outcome-related change experienced by participating community residents vary across and/or between project sites? What factors, if any, appear to be linked to these changes? 3. To what extent and in what ways do the activities of the WaterMarks projects appear to have in situ effects related to the experience of place at project sites?
The project’s research team led by PI Ryan Holifield and Co-PI Woonsup Choi, will investigate how visual artistic activities introduced by the programming team as part of the Walks (and potentially other engagement activities) interact with personal, sociocultural, and physical contexts to produce distinctive experiences and outcomes of informal science learning about urban water systems. The aim of the research will be to synthesize the results from the different WaterMarks sites into an analysis generalizable beyond specific neighborhoods and applicable to other cities. The project's research questions include: 1. How does participation in Walks focused on visual artistic activities affect outcomes and experiences of informal STEM learning about urban water systems? 2. How do outcomes and experiences of informal STEM learning vary across different urban water topics, participants from different demographic groups, and contrasting sociocultural and biophysical contexts?
This Innovations in Development project is led by the University of Wisconsin-Milwaukee (UWM), in collaboration with City as Living Laboratory (CALL) and the COSI Center for Research and Evaluation.
The impacts of changes in the climate at local and global levels threaten how people live. Some frontline communities, especially in historically disenfranchised and under-resourced areas, are particularly vulnerable to the devastating effects of climatological events such as wildfires, flooding, and urban heat islands. As such, there is an urgent need for collective, evidence-based understanding and engagement to prevent and prepare for these potentially fatal events. Led by the Oregon Museum of Science and Industry (OMSI) in Portland, Oregon, in collaboration with local and national partners, Youth Lead the Way is an early-stage Innovations in Development project that offers a theory-based approach for youth in climatologically vulnerable communities to work in climate science research alongside field researchers, develop leadership skills, and engage in timely conversations that impact their own communities. The project will develop and evaluate a Youth Advisory Research Board model to equip and support youth and informal STEM education institutions to conduct evidence-based research on local climate impacts and communicate the findings of their research to their communities. Youth Lead the Way advances the work of several previous NSF-funded projects on climate education, youth advisory boards, and collaborative networks to engage the public in informal STEM learning. Findings from this project will support ongoing efforts in the informal STEM education field to meaningfully engage youth and to more effectively communicate science related to climate and its impacts to the public.
During this initial two-year early-stage project, youth predominantly from racial and ethnic groups underrepresented in STEM will engage in a year-long extended STEM experience. These youth will work collaboratively with scientists and museum professionals to enhance their skills as climate researchers, science communicators, and educational leaders, while reaching an estimated 4,000 or more public audience members through research and events at OMSI, in their schools, and in their communities. Using a cohort model, the youth will conduct scientifically based research studies on various local climate impact topics while concurrently serving in an advisory role at the Oregon Museum of Science and Industry, where they will participate in shaping relevant museum programs and practices. The youth will also develop and present climate stories, a communication approach based on storytelling, to raise public understanding and awareness about local climatological changes and impacts. In addition to the youth component, a companion workshop will be held at the Sciencenter in Ithaca, New York, a partner organization, to train staff and formatively assess the feasibility of scaling the model in other museums. At the program level, an exploratory qualitative research study will be conducted to identify the factors of the overall model that contribute to desired outcomes of youth engagement, climate impact education, and informal science education professional development. Interviews, surveys, focus groups, group chats among youth cohort members, and reviews of artifacts generated by the youth will inform this exploratory study. A theory-based guide outlining key findings, considerations, and recommendations will also be produced. The dissemination of this work will be multi-tiered, reaching thousands within the target communities through public programs, professional networks, at conferences, and a live virtual professional development event hosted by the Association for Science-Technology Centers. If successful, Youth Lead the Way will lay the groundwork for a model that promotes youth and public engagement in STEM through climate science research and identifies promising pathways for future research and similar efforts well beyond this project.
This early-stage Innovations in Development project is funded by the NSF Advancing Informal STEM Learning program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants.
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.
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. The Museum of Science, Boston (MOS) and Boston University (BU) will conduct a Pilot and Feasibility Study project that leverages the current Living Laboratory (LL) model and expand it to engage high school students (teens) in experimental psychology research, science communication and science education activities. In LL, which is now an extensive network of museums and university researchers across the country, scientists and museum staff collaborate to engage children in studies on the museum floor and educate caregivers about the research. Multi-site implementation and evaluation of LL has also documented positive impacts for undergraduate researchers. Many sites are eager to extend these benefits to high school students by engaging them as practitioners within the model and by providing them with opportunities to engage in current research, education and communication, thereby helping to foster stronger youth identities with science and its applications in society. This project expands a ten-year LL partnership between MOS and BU to: 1) pilot a program in which high school students both conduct scientific research and engage the public in learning about science; 2) explore strategies for museums and universities to collaboratively engage, support and mentor high school students in science research, communication and education activities; 3) document curricular, other programmatic, and evaluation materials; and 4) convene professional participants to provide feedback on pilot materials, and assess the viability of implementing similar programs at additional sites. Guided by developmental evaluation, these activities will generate knowledge for the field, and act to increase professional capacity to integrate experiences for teens at multiple LL sites in future projects. 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.
An interview with Jacquelynne S. Eccles, an academic researcher, is presented. Eccles states that after enrolling in graduate school at UCLA in Los Angeles, California, she learned more about what it entailed to be an academic researcher. Eccles avers that she is interested in how people make selections. Eccles believe that the expectations for one's performance and the value that one connects to acting well are heavily socialized within the cultural setting as individuals grow up.
This poster was presented at 2017 Campus Office of Undergraduate Research Initiatives (COURI) Symposium, El Paso, TX.
One of the principal challenges of the partnership of scientists and high school students are the existent barriers of language between them (Kim & Fortner, 2007). In other words, since scientists are usefully deemed as characters with higher power, status, and knowledge, students may feel nervous or intimidated, especially when scientists speak jargons and complex language. The best educators have a magical way of engaging their audiences with compelling stories. Even the
Because of the siloed nature of formal educational curricula, students who opt out of STEM coursework, for whatever reason, lose the opportunity to engage with the domain of science almost entirely, thereby closing the door to the STEM workforce pipeline. This disproportionately impacts students of color and women. This project advances an alliance that consists of a consortium of community-engaged partners, including university and k-12 educational agencies, community colleges, community organizations, cultural institutions and local businesses. The project built around this alliance will leverage interdisciplinary spaces in the curriculum, particularly the humanities and social sciences, across academic levels, as a forum for integrating and applying STEM to bear on the practical, social, economic and political issues of modern life. The PIs establish a physical Community STEM Center as an anchoring institution for STEM engagement. This Center will be situated within the community that the alliance serves, bringing STEM opportunities and engagement to students instead of asking them to come where STEM education is currently provided. The activities enacted through the Community STEM Center will focus on enduring problems experienced by the communities, where students, community residents, teachers, and experts from higher education, industry and other community-based entities can come together to work on understanding them and developing evidenced centered advocacy as a means for addressing them. To facilitate the work at the Community STEM Center, the project creates a Community Ambassadors Program (CAP), leveraging participation across alliance members in partnership with the community. This Design and Development Launch Pilot will cultivate the necessary knowledgebase to develop a scalable model for implementation across diverse urban communities.
Technical Summary
This Design and Development Launch Pilot focuses on shifting the narrative of STEM education away from a solitary focus on formalized educational experiences and targets STEM content. This project develops and facilitates a parallel set of activities designed to engage under-represented students in learning how and why STEM is relevant to their lives, and approached through new and non-traditional educational dimensions. The five main objectives of this proposed pilot are to: (1) Develop a pilot alliance of community-engaged partners, including university and k-12 educational agencies, community colleges, community organizations, cultural institutions and industry;(2)Establish a physical Community STEM Advocacy Center as an anchoring institution for change embedded within the community that the pilot alliance serves; (3) Leverage interdisciplinary spaces in curricula, across academic levels, particularly the humanities and social sciences, as a forum for integrating and applying STEM to bear on the practical, social, economic and political issues of modern life; (4) Create a Community Ambassadors Program (CAP), leveraging participation across higher education pilot alliance members in partnership with the community; and (5)Conduct an evaluation of project initiatives and research regarding the usability and feasibility of a systemic approach to developing community-based, interdisciplinary pathways to broaden STEM participation pathways. Efforts to examine the impact of this community-based, interdisciplinary approach concentrates on the proximal outcomes related to STEM interest, self-efficacy and identity. Data will be collected in pre/post format across our three constituent samples: 1) Community STEM Advocacy Center participants; 2) k-12 students; and, 3) postsecondary students. Analysis of data will be conducted through MANCOVAs to account for potential co-variation among construct scores. Qualitative data will also be collected to contextualize findings and enable the development of a rich case study. At least two observations will be conducted in the Community STEM Advocacy Center and the two classroom implementations to document engagement, participant interactions and level of STEM content.
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TEAM MEMBERS:
Kimberly LawlessDonald WinkLudwig Carlos NitscheAixa AlfonsoJeremiah Abiade
There is broad consensus in the international scientific community that the world is facing a biodiversity crisis — the accelerated loss of life on Earth brought about by human activity. Threats to biodiversity have been variously classified by different authors (Diamond 1989, Laverty and Sterling 2004, Brook et al. 2008), but typically include ecosystem loss and fragmentation, unsustainable use, invasive species, pollution, and climate change. Across the globe, traditional and indigenous cultures are affected by many of the same threats affecting biological diversity, including the
American educators and policymakers have often claimed that the arts can have powerful effects in education and that these effects may reverberate far beyond the arts. Arts education has been argued to have social, motivational, and academic repercussions. But are such claims rooted in empirical evidence, or are they unsupported advocacy? The studies in this issue review systematically what is known about the power of the arts to promote learning in non-arts domains. Thus, we focus here only on the claims that have been made about the effects of arts education on cognitive, academic outcomes