Explore awards
Use the filter menu and interactive map to explore the past competitions offered and grants awarded through the Environmental Literacy Program.
To learn more about project findings and outcomes, view the summaries of our grantees’ summative evaluation reports.
CoCoRaHS: The Community Collaborative Rain, Hail and Snow Network
The Community Collaborative Rain, Hail and Snow Network (CoCoRaHS) involves thousands of people of all ages in the observation and study of weather, climate and water resources. In CoCoRaHS, citizens of all ages help measure and report rain, hail and snow from their own homes, schools and businesses. These data are then efficiently collected via the internet, archived in a national database, and made immediately available to participants, scientists and the general public showing the fascinating patterns of precipitation from each passing storm (see http://www.cocorahs.org). The measurement of precipitation and the patterns, variations and impacts that result, open the door to creative study of our environment. It is the "lowest common denominator" of hydroclimatic exploration. In this project, data from the CoCoRaHS citizen science network will be shared with and utilized by NOAA partners to help monitor drought, to help detect local severe storms, to alert local authorities to developing flash flood situations, to provide "ground truth" for NOAA and NASA remote sensing technologies, and to provide verification for both local and national weather and climate forecast products.
Environmental Service-Learning Project (ESLP)
The Great Lakes Science and Service Learning Initiative (GLSSLI) is a collaborative effort to take Earth Force's proven science-based service learning approach to scale in Michigan by institutionalizing the model within Michigan school districts. By working with the Michigan Community Service Commission's Learn & Serve program and the Great Lakes Stewardship Initiative we are able to leverage statewide structures to make grants directly to school districts, support school districts as they institutionalize the programs and provide on-going professional development to educators. Scaling the GREEN model will deepen student understanding of science by working directly on the environmental problems facing their communities and develop the skills and personal commitment inherent in environmental literacy.
Great Lakes Rocks: Earth Systems Science Teacher Professional Development
The Museum of Science and Industry, Chicago (MSI) offers teacher professional development courses geared toward 4-8th grade teachers in high needs schools and with limited experience in science content. Through the Great Lakes Revealed (GLR) education course, teachers explored the interconnectedness of the Earth’s systems through the unique lens of the Great Lakes region, and learned how climate has changed through time. Through hands-on and inquiry-based activities, MSI Senior Educators guided teacher through lessons and other resources, modeling content and pedagogy best practices, and encouraging knowledge building through a combination of experience, critical thinking and reflection. Participants also interacted with NOAA’s Science on a Sphere, with educators at Thunder Bay National Marine Sanctuary, and with scientists from Great Lakes Environmental Research Laboratory. Formal evaluation shows that GLR teachers complete the program with substantially improved content knowledge, teaching skills, and confidence in science teaching, many becoming teacher leaders at their schools. The second stage of the GLR program involves a select group of teachers from the first year’s cohort who will deepen their understanding of climate change in the Great Lakes region by engaging in data-driven problem-based activities. Building on teachers’ content knowledge, this program will help teachers develop mechanisms to search, access, and use high quality tabular, graphical, and visual data to support effective climate change education. NOAA’s Science on a Sphere datasets will play a central role as teachers explore and then develop their own problem-based lessons to deliver to their own students during a Student Summit at MSI.
R4Ed: Rigor, Relevance, and Relationships in Resilience Education
Rigor, Relevance, and Relationships in Coastal Louisiana Resilience Education (R4Ed) helped high school students in coastal Louisiana learn through data analysis about the science of hurricanes in a warming world, learn through local stories about impacts of hurricanes, and then identify resilient actions that could help keep their households and their communities safe. To accomplish this the UCAR Center for Science Education worked with the NCAR Capacity Center for Climate and Weather Extremes and the South Louisiana Wetlands Discovery Center to develop a high school curriculum called Hurricane Resilience. During 20 days of instruction, students make connections between the science of hurricanes, how they affect their community and region, and how we can plan for a more resilient future. Making local connections, students develop an understanding of 1) the risks that their community faces now and in the future due to hurricanes and tropical storms, 2) how sea level rise increases the risk, and 3) how our actions can help us be less vulnerable and more resilient. The curriculum unit aims to empower high school students to have a voice in resilience planning and understand the relationship between the science of hurricanes and the local impacts these storms have on people and places. Hurricane Resilience is available online and adaptable for high schools in any coastal location where hurricanes pose a threat. The R4Ed project worked with science curriculum coordinators in Terrebonne and Lafourche Parishes, Louisiana, to ensure that the curriculum would meet the needs of their districts. We pilot tested the curriculum in three high school environmental science classes at South Terrebonne High School in Houma, Louisiana. The final curriculum was modified to work for in-person, hybrid, and virtual learning formats during the pandemic. The implementation was scaled up to serve 600 students instructed by 12 teachers in Terrebonne and Lafourche Parishes, LA, during the 2020-2021 school year and then approximately 1000 students during the 2021-2022 school year. Teacher professional development workshops instructed virtually when Covid-19 risk was high and in-person when risk was lower, oriented teachers to the lessons. Over the course of this project, Hurricane Resilience reached 1658 students and approximately 80 educators. In addition, the project reached 220 members of the public during a community event in 2019. Evaluation results indicated that resilience was not part of the environmental science curriculum prior to Hurricane Resilience and 92% of the teachers in this project had never addressed resilience in their environmental science curriculum before this project. Teachers instructing Hurricane Resilience indicated that the curriculum engaged students in concepts that impact their daily lives and the future of their community. We continue to support implementation of Hurricane Resilience in area schools and find ways to build on this foundation, assisting young people as they develop decision making strategies that will help them navigate risk and decrease vulnerability as related to hurricanes, climate change, and sea level rise in the rapidly changing Louisiana Bayou.
Citizen Science, Civics, and Resilient Communities (CSCRC)
The "Citizen Science, Civics, and Resilient Communities” (CSCRC) project led by the Museum of Science, Boston in partnership with Arizona State University, Northeastern University, SciStarter, and the National Informal STEM Education Network (NISE Net), engaged thousands of public participants around the United States in participatory data collection and community deliberation about four climate-related hazards: heat waves, sea level rise, extreme precipitation, and drought. The aims of the project were to increase resilience to extreme weather and environmental hazards through the inclusion of community-generated data, local knowledge, and community values into civic planning, and to increasing capacity among science centers and informal educators for including publics in resilience planning and data collection. The project formulated, iterated, and evaluated a science-to-civics model that included agenda-setting, decision-making and policy forming phases. These activities were developed and implemented by educators at 30 US science centers in collaboration with local resilience planners. Groups of participants in each community collected, analyzed, and shared data about locally relevant hazards; learned about vulnerabilities through visualizations of geospatial data; participated in deliberative, participatory resilience planning and shared perspectives about resilience strategies and their societal and environmental trade-offs; formulated community resilience plans that brought forth diverse perspectives; and presented their findings and recommendations to resilience planners and publics. Participants contributed community-generated data such as urban heat island maps, precipitation data from rain gauges, or documented extreme events through photos of their communities. These data were visualized through StoryMaps, exhibited at local libraries and fairs, and used to facilitate community discussions about the tradeoffs of proposed resilience strategies. Many of the deliberation and participatory science activities pivoted to online formats in response to the pandemic. These digital engagement activities provided new and unanticipated challenges, but also new opportunities connect project participants and capture participant engagement in powerful ways. Our project evaluation found that citizen science and Forum participants increased their knowledge around climate hazards, resilience strategies and their tradeoffs. Participants also increased their confidence and interest in engaging with climate topics, including ways to take action around community climate hazards, contributing to citizen science efforts, and contributing to public policy. Museum professionals found that the project positively impacted their ability to implement science to civics activities, felt supported by the trainings and materials, and planned to continue implementing these programs provided they had continued access to materials, tools, and experts. Many of the project materials are freely available for download at nisenet.org/cscrc and the local project portals documenting the citizen science activities can be found at scistarter.org/noaa.
HEARTForce: Hazard Education, Awareness & Resilience Taskforce
Communities in Colorado are increasingly experiencing major disruptions from environmental hazards, such as wildfire, flood, and drought. With this rise in hazardous events, there is a pressing need for communities to increase their resilience. An interdisciplinary team from the Cooperative Institute for Research in Environmental Sciences (CIRES) Education & Outreach Program at the University of Colorado at Boulder has developed and implemented an innovative, action-oriented youth engagement project that targets rural Colorado students, teachers, and communities. Our engagement model 15 empowers youth i) to envision community resilience through immersive scenario-based role play based using a solid understanding of the relevant science, ii) to learn about natural hazards through engaging place-based lessons, iii) to initiate conversations about hazard preparedness from within communities, and iv) to develop and implement student-led resilience action projects and participate in community resilience expos. A needs assessment disseminated to Colorado teachers guided the project team in the development of all instructional materials and allowed for customizing the content to teacher needs. The project team developed three units (one of wildfire, flood, and drought) for middle and high school students that consist of three parts: place-based data-focused lessons to introduce the hazard, a scenario-based role-play game with a focus on youth empowerment, and a design challenge for students to develop an idea for a resilience action project. Teachers can choose to teach any or all parts and invite community resilience stakeholders and practitioners to share their work with their students, and support students in designing and implementing action projects. Some teachers and students chose to host a Community Resilience Expo, where they invited the public to learn more about the hazard and what resources exist in the community to help prepare for the hazard. The project aimed to accomplished the following three objectives: 1) Increase Colorado secondary teachers’ knowledge and confidence to teach about local natural hazards, and to facilitate discussions about community resilience; 2) Increase Colorado youth’s understanding of natural hazards, their community’s vulnerability, and their involvement in resilience planning efforts, and 3) Enhance the capacity and empowerment of young people in Colorado to engage in dialogue with their peers, families, and community stakeholders about community resilience issues and identify, develop, and implement resilience actions. The project evaluation explored the efficacy of the program model and studied the impact of the project activities on students and teachers. The project filled a critical gap in Colorado’s resilience planning which does not include teachers and youth. The project was guided by partners from the NOAA RISA program Western Water Assessment, seven NOAA science advisors, and was implemented together with over 40 community partners, school partners and collaborators from across Colorado. Over the course of the four-year program, the project trained and supported 88 teachers, engaged nearly 2,000 students, and resulted in 9 Resilience Expo events across rural Colorado.