The Arctic Harvest-Public Participation in Scientific Research (which encompasses the Winterberry Citizen Science program), a four-year citizen science project looking at the effect of climate change on berry availability to consumers has made measurable progress advancing our understanding of key performance indicators of highly effective citizen science programs.
DATE:
TEAM MEMBERS:
Angela LarsonKelly KealyMakaela Dickerson
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.
Environmental educators have used guided-inquiry in natural and supportive learning environments for decades, but comparatively little programming and research has focused on experiences in urban environments, including in constructed ecosystems like green roofs, or impacts on older youth and adults. To address this gap, we designed a tiered, near-peer research mentoring program called Project TRUE (Teens Researching Urban Ecology) and used a mixed-methods approach to evaluate impacts on undergraduates serving as research mentors. During the 11-week program, undergraduates conducted
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
Environmental Protectors is a four-year project based at the University of California at Berkeley’s Lawrence Hall of Science. The project is designed to explore the educational and developmental impact of an informal science education programming model that features Community and Citizen Science (CCS) activities for youth of color residing in urban communities. The project is grounded in hypothesis that CCS-focused experiences result in learning outcomes that better position youth of color to more effectively engage in Science, Technology, Engineering, and Mathematics (STEM) related educational, occupational, and civic activities. Each year, in three economically challenged urban communities located throughout the country, youth of color between the ages of 14 and 18 will participate in month-long summer or semester-long afterschool programs. These programs will feature CCS-related activities that include collection, analysis, interpretation and presentation of data that addresses local, pressing environmental quality concerns, such as soil lead contamination and air particulate matter pollution. The project will use a mix of qualitative and quantitative data collection and analysis to assess the impact of youth engagement in these CCS activities. Overall, through its implementation the project aims to generate information useful in nationwide efforts designed to identify effective strategies and approaches that contribute to increasing STEM understanding and interest among youth of color.
Project research is guided by the following questions: A) What are ways to increase STEM engagement among those who have typically been underrepresented in Community and Citizen Science (CCS) research projects in particular and STEM in general? B) When youth are engaged in CCS, what outcomes are observed related to their science agency and science activism? What other unanticipated outcomes are observed related to benefits of participation and learning? C) How does science activism develop in youth participating in CCS?; and D) How do differences in program implementation impact youth outcomes. In particular, the project explores the manner in which particular CCS activities (e.g., project design, data analysis and interpretation, data presentation) impact youth “Science Agency,” defined as a combination of constructs that include Science Identity (i.e., sense of themselves as science thinkers), Science Value (i.e., awareness of the potential benefits of applying scientific practices to addressing critical community health and environmental issues) and Science Competency Beliefs (i.e., belief of themselves as competent science practitioners) and “Science Activism,” defined as a combination of perceived behavioral control and personal salience. Through its execution the project will refine a theory of learning that makes explicit connections between these constructs. Information derived from the execution of the project will contribute to deeper understanding of the potential for using of CCS projects as a key component of science education environments in urban areas and in general.
This Research in Service to Practice project is funded by the Advancing Informal STEM Learning (AISL) program.
This Innovations in Development project is funded by the 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. Specifically, this project connects Native Hawaiian youth ages 12-17 and their family members to STEM by channeling their cultural relationship with ʻāina, the sustaining elements of the natural world including the land, sea, and air. This project seeks to: broaden participation of Native Hawaiian youth who have been historically underrepresented in STEM; actively uphold Native Hawaiian ways of knowing and traditional knowledge; articulate the science rooted in cultural wisdom; and bring STEM into the lives of participants as they connect to the ʻāina. In partnership with six ʻāina-based community organizations across Hawaiʻi, this project will develop, implement, and study ʻāina-centered environmental education activities that explore solutions to local environmental problems. For example, in one module youth and their families will explore of a section of a nearby stream; identify and discuss the native, non-native, and invasive species; remove invasive species from a small section of the stream and make observations leading to discussions of unintended consequences and systemic impacts; ultimately, learners will meet at additional local waterways to engage in similar explorations and discussions, transferring their knowledge to understanding the impacts of construction on local streams and coral reefs. To this effort, the community-based organizations bring their expertise in preserving Hawaiian culture and sustainable island lifestyle, including rural and urban systems such as farming and irrigation traditions and the restoration of cultural sites. University of Hawai’i faculty and staff bring expertise in Environmental Science, Biology, Hawaiian Studies and Problem-Based Learning Curriculum Development. This project further supports organizational learning and sharing among the six community-based organizations. Grounded in Hawaiian ʻAʻo, where learning and teaching are the same interaction, community-based organizations will create a Community of Practice that will co-learn Problem-Based Learning pedagogy; co-learn and engage in research and evaluation methods; and share experiential and traditional knowledge to co-develop the ʻāina-based environmental education activities.
This project is uniquely situated to study the impact of community-led culturally relevant pedagogy on Hawaiian learners’ interests and connections to environmental science, and to understand ʻāina-based learning through empirical research. Research methods draw on Community-Based Participatory Research and Indigenous Research Methods to develop a collaborative research design process incorporated into the project’s key components. Community members, researchers, and evaluators will work together to examine the following research questions: 1) How does environmental Problem-Based Learning situate within ʻāina-based informal contexts?; 2) What are the environmental education learning impacts of ʻāina-based activities on youth and family participants?; and 3) How does the ʻāina-centered Problem-Based Learning approach to informal STEM education support STEM knowledge, interest and awareness? The evaluation will employ a mixed-methods participatory design to explore program efficacy, fidelity, and implementation more broadly across community-based sites, as well as program sustainability within each community-based site. Anticipated project outcomes are a 15-week organizational learning and sharing program with six ʻāina-based community organizations and 72 staff; the design and implementation of 18 activities to reach 360 youth and at least one of their family members; and the launch of an ʻāina-based STEM Community of Practice. The project’s research and development process for ʻāina-centered environmental education activities will be shared broadly and provide a useful example for other organizations locally and nationally working in informal settings with Native or Indigenous populations.
WCS Education is committed to creating a diverse and inclusive movement of conservation advocates. We do this by creating equitable pathways to increased scientific literacy, engagement in conservation advocacy, and lasting connection with animals and nature.
One of the programs that incorporates all of these strategies is Project TRUE (Teens Researching Urban Ecology). Project TRUE is a partnership between WCS and Fordham University that is both a social science research study and a youth development program designed to support youth in STEM career pathways. Teams of high school students
This book chapter describes zoo and aquariums' history of conservation education programming for students and teachers. It showcases several examples of student-teacher-scientist partnerships, including Project TRUE, highlighting the program's success at cultivating sustained interest in science careers among high school youth.
Zoos and aquariums have a long history of providing conservation education to students and teachers. As the conservation work of zoos and aquariums has grown, so have the opportunities to connect students and teachers to the work of these scientists. This chapter
Preparing mentors for their role is essential. Though most research tells us that you cannot teach or train someone how to be a mentor, there is tremendous value in preparing mentors for their upcoming experience through self-reflection, setting expectations, and discussion.
Ultimately, mentors will learn and develop their skills while they are mentoring. For this reason, in addition to preparing mentors for their role, it is critical to create a supportive and inclusive community to support mentors during their mentoring experience.
This “Mentoring Training Toolkit” distills what was
The field of ecology is poised to substantially contribute to the creation of a socially and environmentally equitable urban future. To realize this contribution, the field of ecology must create strategies that ensure inclusion of underrepresented minorities so that a broad array of experiences and ideas collectively address challenges inherent to a sustainable urban future. Despite efforts to recruit and retain underrepresented racial minorities (URM) in the sciences, graduation rates have only slightly increased over the last several decades. While research mentoring programs at the