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1. Water Monitoring of the Choptank River and Pocomoke River, Maryland, USA

   https://doi.org/10.6073/pasta/54fecf9652c2e4d93e92d64388e6c3eb  

   Ensign, Scott H; Kan, Jinjun (September 2024, Environmental Data Initiative)

   Water monitoring at four locations on the Choptank River and four locations on the Pocomoke River in Maryland, U.S.A., was conducted from 2021 through 2023. Funding and scientific rationale were provided by the National Science Foundation grant 2049073 (“Resolving Sediment Connectivity between Rivers and Estuaries by Tracking Particles with their Microbial Genetic Signature”). The monitoring locations were chosen to measure estuary dynamics from the tidal freshwater zone through the mesohaline estuary. Parameters measured included water temperature, water level, water conductivity (reported as specific conductivity), water turbidity, and water velocity. 

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2. River Discharge

   Holmes, R; Shiklomanov, A; Suslova, A; Tretiakov, M; McClelland, JW; Spencer, RGM; Tank, SE. (January 2018, Arctic report card)
3. Code and data for mapping and classification of meandering river bends on the Beatton River, Canada

   https://doi.org/10.5281/zenodo.14991479  

   Limaye, Ajay B (March 2025, Zenodo)

   This archive contains MATLAB code for mapping and classification of meander bends, including example data for the Beatton River, Canada, as described in two articles in Journal of Geophysical Research: Earth Surface:   Limaye, A. B., 2025, A geometric algorithm to identify river meander bends: 1. Effect of perspective Limaye, A. B., 2025, A geometric algorithm to identify river meander bends: 2. Test for characteristic shapes 

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4. River Microbiome and Watershed Characteristics Analysis

   https://doi.org/10.5281/zenodo.3902478  

   URycki, Dawn R; Good, Stephen P (January 2020, Zenodo)

   This entry contains the data and code for the analysis described in URycki DR, Good SP, Crump BC, Chadwick J and Jones GD (2020) River Microbiome Composition Reflects Macroscale Climatic and Geomorphic Differences in Headwater Streams. Frontiers in Water 2:574728. doi: 10.3389/frwa.2020.574728 Abstract: Maintaining the quality and quantity of water resources in light of complex changes in climate, human land use, and ecosystem composition requires detailed understanding of ecohydrologic function within catchments, yet monitoring relevant upstream characteristics can be challenging. In this study, we investigate how variability in riverine microbial communities can be used to monitor the climate, geomorphology, land-cover, and human development of watersheds. We collected streamwater DNA fragments and used 16S rRNA sequencing to profile microbiomes from headwaters to outlets of the Willamette and Deschutes basins, two large watersheds prototypical of the U.S. Pacific Northwest region. In the temperate, north-south oriented Willamette basin, microbial community composition correlated most strongly with geomorphic characteristics (mean Mantel test statistic r = 0.19). Percentage of forest and shrublands (r = 0.34) and latitude (r = 0.41) were among the strongest correlates with microbial community composition. In the arid Deschutes basin, however, climatic characteristics were the most strongly correlated to microbial community composition (e.g., r = 0.11). In headwater sub-catchments of both watersheds, microbial community assemblages correlated with catchment-scale climate, geomorphology, and land-cover (r = 0.46, 0.38, and 0.28, respectively), but these relationships were weaker downstream. Development-related characteristics were not correlated with microbial community composition in either watershed or in small or large sub-catchments. Our results build on previous work relating streamwater microbiomes to hydrologic regime and demonstrate that microbial DNA in headwater streams additionally reflects the structural configuration of landscapes as well as other natural and anthropogenic processes upstream. Our results offer an encouraging indication that streamwater microbiomes not only carry information about microbial ecology, but also can be useful tools for monitoring multiple upstream watershed characteristics. 

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5. River Deltas and Sea-Level Rise

   https://doi.org/10.1146/annurev-earth-031621-093732  

   Nienhuis, Jaap H.; Kim, Wonsuck; Milne, Glenn A.; Quock, Melinda; Slangen, Aimée B.A.; Törnqvist, Torbjörn E. (May 2023, Annual Review of Earth and Planetary Sciences)

   Future sea-level rise poses an existential threat for many river deltas, yet quantifying the effect of sea-level changes on these coastal landforms remains a challenge. Sea-level changes have been slow compared to other coastal processes during the instrumental record, such that our knowledge comes primarily from models, experiments, and the geologic record. Here we review the current state of science on river delta response to sea-level change, including models and observations from the Holocene until 2300 CE. We report on improvements in the detection and modeling of past and future regional sea-level change, including a better understanding of the underlying processes and sources of uncertainty. We also see significant improvements in morphodynamic delta models. Still, substantial uncertainties remain, notably on present and future subsidence rates in and near deltas. Observations of delta submergence and land loss due to modern sea-level rise also remain elusive, posing major challenges to model validation. ▪ There are large differences in the initiation time and subsequent delta progradation during the Holocene, likely from different sea-level and sediment supply histories. ▪ Modern deltas are larger and will face faster sea-level rise than during their Holocene growth, making them susceptible to forced transgression. ▪ Regional sea-level projections have been much improved in the past decade and now also isolate dominant sources of uncertainty, such as the Antarctic ice sheet. ▪ Vertical land motion in deltas can be the dominant source of relative sea-level change and the dominant source of uncertainty; limited observations complicate projections. ▪ River deltas globally might lose 5% (∼35,000 km 2 ) of their surface area by 2100 and 50% by 2300 due to relative sea-level rise under a high-emission scenario. Expected final online publication date for the Annual Review of Earth and Planetary Sciences, Volume 51 is May 2023. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates. 

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