The Water Resources Agency and its affiliated agencies provide relevant range information for various river basins for use by government agencies and private organizations, groups, or academic units commissioned by government agencies for specific projects. This dataset is linked to a Keyhole Markup Language (KML) file list, a markup language based on the XML (eXtensible Markup Language) syntax standard, used to express geographic annotations. KML files, written in the KML language, use the XML file format and are applied in Google Earth-related software for displaying geographic data (including points, lines, polygons, models, etc.). Many GIS systems also use this format for exchanging geographic data. The KML data in this dataset uses the UTF-8 encoding.

Maps of river basins of India. Also includes Cauvery river basin map separately.

The High Plains aquifer extends from south of 32 degrees to almost 44 degrees north latitude and from 96 degrees 30 minutes to 104 degrees west longitude. The aquifer underlies about 175,000 square miles in parts of Colorado, Kansas, Nebraska, New Mexico, Oklahoma, South Dakota, Texas, and Wyoming. The Republican River Basin is about 25,000 square miles and is located in northeast Colorado, northern Kansas, and southwest Nebraska. The Republican River Basin overlies the High Plains aquifer for 87 percent of the basin area. This dataset consists of a raster of water-level changes for the High Plains aquifer, in the Republican River Basin, 2002 to 2015. This digital dataset was created using water-level measurements from (1) 977 wells, which are located in the Republican River Basin, and (2) 546 wells, which are located within 20 miles outside the boundary of the Republican River Basin. These 1,523 wells were measured in both 2002 and in 2015. The map was reviewed for consistency with the relevant data at a scale of 1:1,000,000.

Regional geophysical maps of the Great Basin, USA were generated from new and existing sources to support ongoing efforts to characterize geothermal resource potential in the western US. These include: (1) a provisional regional gravity grid that was produced from data compiled from multiple sources: data collected by the USGS and Utah Geological Survey under various projects, industry sources, and regional compilations derived from two sources: a Nevada state-wide database (Ponce, 1997), and a public domain dataset (Hildenbrand et al., 2002), (2) a regional magnetic grid derived from the North American magnetic compilation map of Bankey et al. (2002) and, (3) a regional depth-to-basement grid derived from Shaw and Boyd (2018). References: Bankey, V., Cuevas, A., Daniels, D., Finn, C.A., Hernandez, I., Hill, P., Kucks, R., Miles, W., Pilkington, M., Roberts, C., Roest, W., Rystrom, V., Shearer, S., Snyder, S., Sweeney, R.E., Velez, J., Phillips, J.D., and Ravat, D.K.A., 2002, Digi ...

This basins dataset was created to initiate regional watershed approaches with respect to sewer rehabilitation.

This package contains a project specific geodatabase and map (.mxd) for River Basin and modeling projects. For directions on using this file, see the GIS Standards Technical Memorandum on the Standards Page.

The major river basin lines in NC are drawn based on the nationally recognized hydrologic unit codes (6-digits). Some basins have been split apart due to previously written general statutes. This feature service was uploaded in December 2014. This feature layer can be found in the NC Surface Water Classification map application.

This resource is a repository of the map products for the Annual Irrigation Maps - Republican River Basin (AIM-RRB) dataset produced in Deines et al. 2017. It also provides the training and test point datasets used in the development and evaluation of the classifier algorithm. The maps cover a 141,603 km2 area in the northern High Plains Aquifer in the United States centered on the Republican River Basin, which overlies portions of Colorado, Kansas, and Nebraska. AIM-RRB provides annual irrigation maps for 18 years (1999-2016). Please see Deines et al. 2017 for full details.

Preferred citation: Deines, J.M., A.D. Kendall, and D.W. Hyndman. 2017. Annual irrigation dynamics in the US Northern High Plains derived from Landsat satellite data. Geophysical Research Letters. DOI: 10.1002/2017GL074071

Map Metadata Map products are projected in EPSG:5070 - CONUS Albers NAD83 Raster value key: 0 = Not irrigated 1 = Irrigated 254 = NoData, masked by urban, water, forest, or wetland land used based on the National Land Cover Dataset (NLCD) 255 = NoData, outside of study boundary

Training and test point data sets supply coordinates in latitude/longitude (WGS84). Column descriptions for each file can be found below in the "File Metadata" tab when the respective file is selected in the content window.

Corresponding author: Jillian Deines, jillian.deines@gmail.com

These grid files were used to produce gravity and basin depth maps of the Basin and Range Province, western United States. The maps show gravity values and modeled basin depths in this area. The data were compiled by the U.S. Geological Survey, Denver, Colorado. This data base was received in June, 1995. For further information see the readme.txt file in this directory(data\grids\basinrng), and the "Gravity and Basin-Depth Maps of the Basin and Range Province, Western United States", by R.W. Saltus and R.C. Jachens, Map GP-1012.

Hydrology of the Kuparuk River basin, including streams, rivers, ponds, lakes, and coastline. The map includes line features as well as polygon features (.shp). This map was drawn by Skip Walker, derived by interpreting the CIR version of the GTOPO30 Landsat MSS image created in 1999 by Jiong Jia. Go to Website Link :: Toolik Arctic Geobotanical Atlas below for details on legend units, photos of map units and plant species, glossary, bibliography and links to ground data. Map Themes: Elevation, Hydrology, Landscape, Landsat MSS False-Color Infrared, Vegetation References Muller, S. V., Walker, D. A., Nelson, F. E., Auerback, N. A., Bockheim, J. G., Guyer, S., & Sherba, D. 1998. Accuracy assessment of a land-cover map of the Kuparuk river basin, Alaska: considerations for remote regions. Photogrammetric Engineering and Remote Sensing, 64(6): 619-628.

A series of maps that show water monitoring stations (gauging stations) across New South Wales. This map series, formerly known as the Pinneena maps, was created as part of a major project in 2011.

Each map includes stations which fall in the following categories:

Current with significant data: Gauging stations that were active and have significant data or had been established as of March 2011.

Current without significant data: Gauging stations that were active but didn't have significant data as of March 2011.

Discontinued or moved: Gauging station that had been closed or moved to another organisation to maintain as of March 2011.

A water monitoring station (gauging station) is a location on a stream, canal, lake or reservoir from which an observer or tool takes systematic readings of the gauge height or discharge. Hydrologists use these continuous records to make predictions and decisions concerning water level, flood activity and control, navigation, and the like. Note: The maps are best displayed at A3 paper size. Data disclaimer These water monitoring station maps were created as part of a project completed in March 2011, and have not been updated to include more recent data or information. The information contained in these maps should be used as a reference only, as the actual location or category of some gauging stations may have changed.

The maps use the following datasets (all licensed under ‘Creative Commons Attribution’) supplied by other agencies:

Spatial Services (New South Wales Department of Customer Service) Hydro Line (Rivers/Creeks) spatial data is a dataset of mapped watercourses and waterbodies in NSW. They can be referenced as ‘ NSW Foundation Spatial Data Framework – Water – NSW Hydro Line’. © Spatial Services [2011]

Australian Government Bureau of Meteorology Australia’s River Basins (Catchment boundaries) spatial data uses the Australia’s River Basin 1997 dataset. Citation: 1997. Australia's River Basins 1997. Geoscience Australia, Canberra. http://pid.geoscience.gov.au/dataset/ga/42343 For more information http://www.bom.gov.au/water/about/riverBasinAuxNav.shtml

WaterNSW Real time data of monitoring stations can be accessed through WaterNSW Real-time data website: https://www.waternsw.com.au/waterinsights/real-time-data Reference: The material is subject to copyright under the Copyright Act 1968, and it is owned by the State of New South Wales through WaterNSW. WaterNSW encourages the availability, dissemination and exchange of public information. You may copy, distribute, display, download and otherwise freely deal with the information for any purpose, on the condition that you include the copyright.

Note: In addition to the attached individual catchment maps PDFs (which can be printed off one at a time), there is also a MERGED version consolidating all of the individual PDFs into a single ATLAS of Maps PDF. This particular pdf (which is designed to be printed A3 back-to-back) is attached and titled: zz_PINNEENA_A3_MARCH2011_FINAL.pdf

This data set provides high-resolution (~500 m) gridded land and stream drainage direction maps for the Amazon River basin, excluding the Rio Tocantins basin. These maps are the result of a new topography-independent analysis method (Mayorga et al., 2005) using the vector river network from the Digital Chart of the World (DCW, Danko, 1992) to create a high-resolution flow direction map.

The data products include (1) a stream network coverage with stream order assigned to each reach; (2) the basin boundaries of the major tributaries to the Amazon mainstem; (3) the mouths; and (4) the source points of these tributaries.

There are 7 ESRI ArcGIS shapefiles provided in compressed *.zip format and 4 GeoTiff image files with this data set.

The North Coast Basin Plan Web Map contains layers for the North Coast Region Basin Plan Web Application. Currently the map has 29 layers and most have been separated into different categories. The categories are Basin Plan, CIWQS, Ecology, Hydrology, and Jurisdiction. Most of the layers were obtained from different organizations including, but not limited to, NOAA, CDFW, and CalFire. Some layers were developed specifically for the North Coast Basin Plan Web Application including the 2014-2016 Integrated Report Lines and Polygons and the TMDL Watersheds layers. Point of Contact: Lance Le, Water Resource Control Engineer in the Planning and Watershed Stewardship Division in The North Coast Regional Water Quality Control Board. Email: Lance.Le@Waterboards.ca.gov

High-quality, multi-client 3D seismic data covering the Powder River Basin in Wyoming. This dataset supports deep imaging and subsurface exploration of the Wyoming Powder River Basin, including tertiary and Pennsylvanian rocks. The page features Powder River Basin map coverage and seismic attributes relevant to hydrocarbon-rich formations.

Open the Data Resource:https://gis.chesapeakebay.net/wip/meboverview/ This story map provides more information about the 2024 Most Effective Basins mapping project. It complements an interactive map and downloadable dataset. A total of $23 million has been directed to support Most Effective Basins (MEB) implementation in FY2024. MEBs targeted for this funding were identified based on load effectiveness, which is a measure of the ability of management practices implemented in each area (basin) to have a positive effect on dissolved oxygen in the Chesapeake Bay. Unless otherwise approved, implementation activities are expected to occur within these areas.

The Red River Basin: The International Joint Commission (IJC) of Canada and the United States developed this Esri Web Map Series to provide a structured geographic overview of shared drainage basins that span the Canada-U.S. border. This series was specifically designed to be incorporated into a General Esri Story Map that serves as an introduction to transboundary watersheds, highlighting their geographic, environmental, and hydrological significance.Purpose and UseThe Web Map Series is intended to:Offer a general introduction to shared drainage basins along the Canada-U.S. boundary.Provide a consistent spatial reference for transboundary water governance and policy discussions.Serve as a foundational dataset for broader studies on hydrology, environmental management, and cross-border cooperation.Core Features of the Web Map SeriesThe features included in each Web Map vary by basin but generally include the following:Harmonized Drainage BasinsBased on datasets from the United States Geological Survey (USGS) and Environment and Climate Change Canada (ECCC).Provides a unified representation of drainage basins across the international boundary.Indigenous Communities (as interpreted by federal agencies)Displays Indigenous communities based on datasets from Canadian and U.S. federal agencies.This layer does not represent traditional or historical lands, but rather current federally recognized Indigenous lands.Water Level GaugesIncludes real-time and historical water level monitoring stations.Provides hydrological data critical for flood forecasting, drought assessment, and water resource management.Major Hydrological FeaturesDams and Diversions – Identifies hydropower facilities, flood control structures, and major water diversions impacting shared basins.Rivers and Lakes – Highlights significant hydrologic networks that define transboundary watersheds.Populated Places and Place NamesIncludes official municipalities, towns, and cities within and near the basin boundaries.Features official geographic place names from federal, state, and provincial authorities.Protected AreasDisplays Federal, State, and Provincial Parks within transboundary basins.Highlights protected lands relevant to watershed conservation and ecological management.Significance of the Web Map SeriesThe IJC Web Map Series is designed to serve as a foundational geographic tool for decision-makers, researchers, and the public to better understand the shared hydrological systems of Canada and the United States. By integrating authoritative datasets from both countries, this Web Map Series promotes a standardized approach to visualizing transboundary watersheds, supporting cooperative water resource management and policy development.Important Note: The representation of Indigenous or First Nation lands in this Web Map Series does not indicate traditional or historical territories; rather, it reflects data provided by federal agencies in Canada and the United States.This Web Map Series will continue to evolve as new datasets become available, ensuring that transboundary water governance is supported with the most up-to-date and authoritative geographic information.

Geomorphology reference map with basin boundaries and 30m DEM. Also contains derived Wyoming landforms.

This dataset consists of an interactive map (and supporting guidance) containing background information that informs how we understand flood risk across the South West River Basin District. The map shows the River Basin District, component river basins and the coastline together with layers showing land use and topography. This dataset together with equivalent datasets for each River Basin District, supports the Preliminary Flood Risk Assessment for England report which has been written to meet the requirements of the Flood Risk Regulations (2009) - to complete an assessment of flood risk and produce supporting maps of river catchments.

Geothermal well data from Southern Methodist University (SMU, 2021) and the U.S. Geological Survey (Sass et al., 2005) were used to create maps of estimated background conductive heat flow across the greater Great Basin region of the western US. The heat flow maps in this data release were created using a process that sought to remove hydrothermal convective influence from predictions of background conductive heat flow. Heat flow maps were constructed using a custom-developed iterative process using weighted regression, where convectively influenced outliers were de-emphasized by assigning lower weights to measurements that are very different from the estimated local trend (e.g., local convective influence). The weighted regression algorithm is 2D LOESS (locally estimated scatterplot smoothing; Cleveland et al., 1992), which was used for local linear regression, and smoothness was controlled by varying the number of nearby points used for each local interpolation. Three maps are included in this data release, allowing comparison of the influence of measurement confidence: all wells are equal-weight, and two different published categorizations of measurement quality were used to de-emphasize low-quality measurements. Each map is an estimate of background conductive heat flow as a function of assumed data quality, and a point coverage is also provided for all wells in the compiled dataset. The point coverage includes an important new attribute for geothermal wells: the residual, which can be interpreted as the well’s departure from estimated background heat flow conditions, and the value of residual may be useful in identifying hydrothermal or groundwater influence on conductive heat flow. References Cleveland, W. S., Grosse, E., Shyu, W. M, 1992, Local regression models. Chapter 8 of Statistical Models in S eds J.M. Chambers and T.J. Hastie, Wadsworth & Brooks/Cole. Sass, J. H., S.S. Priest, A.H. Lachenbruch, S.P. Galanis, Jr., T.H. Moses, Jr., J.P. Kennelly, Jr., R.J. Munroe, E.P. Smith, F.V. Grubb, R.H. Husk, Jr., and C.W. Mase, 2005, Summary of supporting data for USGS regional heat flow studies of the Great Basin, 1970-1990, USGS Open file Report, 2005-1207. SMU Regional Heat Flow Database, retrieved from http://geothermal.smu.edu on March 29, 2021.

This dataset consists of an interactive map (and supporting guidance) containing background information that informs how we understand flood risk across the Humber River Basin District. The map shows the River Basin District, component river basins and the coastline together with layers showing land use and topography.

This dataset together with equivalent datasets for each River Basin District, supports the Preliminary Flood Risk Assessment for England report which has been written to meet the requirements of the Flood Risk Regulations (2009) - to complete an assessment of flood risk and produce supporting maps of river catchments.