To address the limitations of accurately mapping small artificial water bodies and quantifying their contribution to CH4 emissions, the overarching aim of this proposal is to provide better annual regional CH4 flux estimates from inland waters of the Southeastern US by constraining the spatial and temporal dynamics of small water bodies.
Floods are the most signifigant climate change-related hazards in terms of life loss and economic damage. Effective and immediate disaster response management can reduce the impact of floods, but it requires near real-time information on flood occurrence, typically derived based on Earth Observation data. Our work has applied machine learning algorithms to map floods globally. We also showed that we can detect more ephemeral flooding events when using data from three sensors provided by NASA’s Harmonized Landsat-Sentinel 2 data product, HLS.
Fresh water stored by small on-farm reservoirs (SRs), which are small water bodies, is a fundamental component of surface hydrology and is critical for meeting global irrigation needs. Farmers use SRs to store water during the wet season for crop irrigation during the dry season. SRs can also contribute to downstream water stress by decreasing stream discharge and peak flow in the watersheds where they are built. There are more than 2.6 million SRs in the US alone, and many SRs were constructed during the last 40 years. Despite their importance for crop irrigation, SRs are poorly quantified bc (1) they are small (
Water stress is a global concern as a changing climate leads to variations in weather patterns and agricultural and urban areas continue to use water-intensive practices. Understanding spatial and temporal factors of surface water dynamics is key to better managing our resources and limiting the effects of water stress. However, many of the models we currently have for estimating changes in surface water do not account for human drivers such as land cover change or land use intensity. In this study, we assessed how different climate and anthropogenic drivers affect the variability of surface water in the Southeastern United States, an area that has experienced more land cover change than any other region in the country.
Reidsville GA Community Floods, a small community group, seeks to prevent residential flooding in Reidsville, GA. This community science project will help residents understand their flood risks and the potential for green infrastructure as a step toward this greater goal. In parallel with the group’s existing partnerships that are investigating county-level flooding, the outcomes of this project are to 1) create a map that outlines flood risk in the community 2) better understand the potential for green infrastructure, including replicable green infrastructure on private property.