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Theodore B. Barnhart

Dr. Theodore B. Barnhart studies the connection between the mountain snowpack and streamflow.

Dr. Barnhart is interested in furthering the understanding of how changes in the mountain snowpack translate into changes in streamflow and how that process varies across landscapes, land cover types, and climate systems. He is also interested in understanding the water resources implications of the changing mountain snowpack and streamflow and the effects on downstream stakeholders. He uses numerical snowpack and hydrologic models for his research along with observational and remote sensing data sets.

Professional Experience

  • Research Physical Scientist, United States Geological Survey, Wyoming – Montana Water Science Center, Helena, MT: 2020-present.

  • Physical Scientist, United States Geological Survey, Wyoming – Montana Water Science Center, Helena, MT: 2017-2020.

  • Research Assistant, Institute of Arctic and Alpine Research, University of Colorado Boulder, Boulder, CO: 2013-2018.

  • Research Assistant, Department of Geology, Idaho State University, Pocatello, ID: 2011-2013.

Education and Certifications

  • PhD Geography, University of Colorado Boulder, 2018.

  • MS Geology, Idaho State University, 2013.

  • BA Geology-Environmental Studies with Honors, Whitman College, 2010, Cum Laude.

Affiliations and Memberships*

  • Present: American Geophysical Union

Science and Products

Tongue River between Tongue River Reservoir and Birney, MT

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving: - a shift in precipitation from snow to rain - changing precipitation intensity and seasonality - increasing atmospheric demand for moisture in mountain river watersheds across the western United States (Seager and others, 2015). These changes will likely alter the timing and quantity of streamflow in rivers draining mountains. The Tongue River flows from the...
By
Water Resources Mission Area, Wyoming-Montana Water Science Center
Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving: - a shift in precipitation from snow to rain - changing precipitation intensity and seasonality - increasing atmospheric demand for moisture in mountain river watersheds across the western United States (Seager and others, 2015). These changes will likely alter the timing and quantity of streamflow in rivers draining mountains. The Tongue River flows from the...
Learn More
Tongue River between Tongue River Reservoir and Birney, MT

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving a shift in precipitation from snow to rain, changing precipitation intensity and seasonality, and increasing atmospheric demand for moisture in mountain river watersheds across the western United States. These changes will likely alter the timing and quantity of streamflow in rivers draining from the mountains. The Tongue River flows from the Bighorn...
By
Climate Adaptation Science Centers
Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving a shift in precipitation from snow to rain, changing precipitation intensity and seasonality, and increasing atmospheric demand for moisture in mountain river watersheds across the western United States. These changes will likely alter the timing and quantity of streamflow in rivers draining from the mountains. The Tongue River flows from the Bighorn mountains in
Learn More
A concrete weir during very low streamflows.

State of the Science in Streamflow Modeling in the North Central Region to Address Partner Needs for Water Availability Under Drought Conditions

Land and water managers often rely on hydrological models to make informed management decisions. Understanding water availability in streams, rivers, and reservoirs during high demand periods that coincide with seasonal low flows can affect how water managers plan for its distribution for human consumption while sustaining aquatic ecosystems. Substantial advancement in hydrological...
By
Climate Adaptation Science Centers
State of the Science in Streamflow Modeling in the North Central Region to Address Partner Needs for Water Availability Under Drought Conditions

State of the Science in Streamflow Modeling in the North Central Region to Address Partner Needs for Water Availability Under Drought Conditions

Land and water managers often rely on hydrological models to make informed management decisions. Understanding water availability in streams, rivers, and reservoirs during high demand periods that coincide with seasonal low flows can affect how water managers plan for its distribution for human consumption while sustaining aquatic ecosystems. Substantial advancement in hydrological modeling has
Learn More
Example FCPG showing stream cells with upstream average annual precipitation.

Flow-Conditioned Parameter Grids

Flow-Conditioned Parameter Grids (FCPGs) are a way of storing the upstream average of datasets, such as precipitation or land cover type, for all points on the landscape.
By
Water Resources Mission Area, Wyoming-Montana Water Science Center
Flow-Conditioned Parameter Grids

Flow-Conditioned Parameter Grids

Flow-Conditioned Parameter Grids (FCPGs) are a way of storing the upstream average of datasets, such as precipitation or land cover type, for all points on the landscape.
Learn More
USGS science for a changing world logo

Building a framework to compute continuous grids of basin characteristics for the conterminous United States

The proposed work will create a seamless pilot dataset of continuous basin characteristics (for example upstream average precipitation, elevation, or dominant land cover type) for the conterminous United States. Basin characteristic data are necessary for training or parameterizing statistical, machine learning, and physical models, and for making predictions across the landscape...
By
Community for Data Integration (CDI)
Building a framework to compute continuous grids of basin characteristics for the conterminous United States

Building a framework to compute continuous grids of basin characteristics for the conterminous United States

The proposed work will create a seamless pilot dataset of continuous basin characteristics (for example upstream average precipitation, elevation, or dominant land cover type) for the conterminous United States. Basin characteristic data are necessary for training or parameterizing statistical, machine learning, and physical models, and for making predictions across the landscape, particularly in
Learn More
Estimated Nitrogen and Phosphorus Input to Fish Creek Watershed

Geospatial Research and Development to Understand Hydrologic Processes

Geospatial Research and Development (GeoRAD) advances understanding of hydrologic processes by using tools and technologies to map, analyze, and visualize water-related data to better understand how water moves and behaves in the environment. Like all natural phenomena, hydrological phenomena occur in specific locations. Remote sensing, GIS, and geostatistical methods are tools that can be used to...
By
Wyoming-Montana Water Science Center
Geospatial Research and Development to Understand Hydrologic Processes

Geospatial Research and Development to Understand Hydrologic Processes

Geospatial Research and Development (GeoRAD) advances understanding of hydrologic processes by using tools and technologies to map, analyze, and visualize water-related data to better understand how water moves and behaves in the environment. Like all natural phenomena, hydrological phenomena occur in specific locations. Remote sensing, GIS, and geostatistical methods are tools that can be used to...
Learn More

Historical simulated snowpack and other hydrometeorology data at 30 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020 Historical simulated snowpack and other hydrometeorology data at 30 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020

This data release contains historical SnowModel (Liston and Elder, 2006) output for the Crown of the Continent and surrounding areas in Montana, USA; and Alberta and British Columbia, Canada from September 1, 1981 through August 31, 2020. Fifteen daily variables were simulated or derived for this release: (1) snow water equivalent (swed), (2) liquid precipitation (rpre), (3) solid...
By
Wyoming-Montana Water Science Center

Historical simulated snowpack and other hydrometeorology data at 90 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020 Historical simulated snowpack and other hydrometeorology data at 90 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020

This data release contains historical SnowModel (Liston and Elder, 2006) output for the Crown of the Continent and surrounding areas in Montana and Idaho, USA; and Alberta and British Columbia, Canada from September 1, 1981 through August 31, 2020. Fifteen daily variables were simulated or derived for this release: (1) snow water equivalent (swed), (2) liquid precipitation (rpre), (3)...
By
Northern Rocky Mountain Science Center

High Resolution Current and Future Climate SnowModel Simulations in the Upper Colorado River Basin High Resolution Current and Future Climate SnowModel Simulations in the Upper Colorado River Basin

This data release contains SnowModel snow evolution simulation output on a 100-meter (m) geospatial grid for a 311 kilometer (km) × 300 km model domain in Colorado, United States, encompassing the Colorado and Gunnison River Basin headwaters in the Upper Colorado River Basin. Weather Research and Forecasting (WRF) Model convection-permitting and orography-resolving (4-km grid spacing)...
By
Colorado Water Science Center

Basin Characteristics and Streamflow Statistics for Selected Gages, Alaska, USA (ver. 2.0, September, 2022) Basin Characteristics and Streamflow Statistics for Selected Gages, Alaska, USA (ver. 2.0, September, 2022)

This data release documents the data used for the associated publication "Evaluating hydrologic region assignment techniques for ungaged watersheds in Alaska, USA" (Barnhart and others, 2022) The data sets within this release are stored in 14 files: (1) Streamflow observations and sites used. (2) Statistically estimated streamflow values computed for each site. (3) Streamflow statistics...
By
Wyoming-Montana Water Science Center

Historical simulated snowpack for the Lake Sherburne, MT watershed and vicinity, water years 1980-2019 Historical simulated snowpack for the Lake Sherburne, MT watershed and vicinity, water years 1980-2019

Abstract This data release contains historical SnowModel (Liston and Elder, 2006) output for the Lake Sherburne, MT watershed and surrounding area. The two quantities simulated for this release were snow water equivalent depth (swed), the liquid water equivalent depth stored as snow in the simulation domain, and runoff (roff), which includes snowmelt at the snow-soil interface and...
By
Wyoming-Montana Water Science Center

Flow-Conditioned Parameter Grids for the Contiguous United States: A Pilot, Seamless Basin Characteristic Dataset Flow-Conditioned Parameter Grids for the Contiguous United States: A Pilot, Seamless Basin Characteristic Dataset

Abstract To aid in parameterization of mechanistic, statistical, and machine learning models of hydrologic systems in the contiguous United States (CONUS), flow-conditioned parameter grids (FCPGs) have been generated describing upstream basin mean elevation, slope, land cover class, latitude, and 30-year climatologies of mean total annual precipitation, minimum daily air temperature, and...
By
Community for Data Integration (CDI), Wyoming-Montana Water Science Center
No results found.
Filter Total Items: 13

Fine-resolution satellite remote sensing improves spatially distributed snow modeling to near real time Fine-resolution satellite remote sensing improves spatially distributed snow modeling to near real time

Given the highly variable distribution of seasonal snowpacks in complex mountainous environments, the accurate snow modeling of basin-wide snow water equivalent (SWE) requires a spatially distributed approach at a sufficiently fine grid resolution (
Authors
Graham A. Sexstone, Garrett Alexander Akie, David J. Selkowitz, Theodore B. Barnhart, David M. Rey, Claudia León-Salazar, Emily Carbone, Lindsay A. Bearup
By
Water Resources Mission Area, Colorado Water Science Center, Wyoming-Montana Water Science Center

Cryospheric sciences at the U.S. Geological Survey Cryospheric sciences at the U.S. Geological Survey

Introduction The cryosphere is the collective parts of the Earth where water is in its frozen state and includes snow, glaciers, ice sheets, ice shelves, freshwater ice, sea ice, and permafrost. The cryosphere is a climate indicator and climate regulator. Surface cryosphere features, such as glaciers, snow, and sea ice, store freshwater and make the surface of the Earth bright white...
Authors
Caitlyn Florentine, Erich H. Peitzsch, Miriam C. Jones, Theodore B. Barnhart, Thomas M. Cronin
By
Ecosystems Mission Area, Northern Rocky Mountain Science Center

Streamflow timing and magnitude during snow drought depend on snow drought type and regional hydroclimate Streamflow timing and magnitude during snow drought depend on snow drought type and regional hydroclimate

Communities around the world rely on snowmelt to meet water demands, and periods of lower than normal snow accumulation, snow droughts, can decrease water supplies. Leveraging 172 minimally disturbed and seasonally snow-covered watersheds, we developed an approach to examine the effects of cool & dry, warm & dry, and warm & wet snow droughts on streamflow timing and magnitude by...
Authors
John C. Hammond, Annie L. Putman, Theodore B. Barnhart, Graham A. Sexstone, Gregory J. McCabe, David M. Wolock, Aaron Joseph Heldmyer, Stephanie K. Kampf
By
Maryland-Delaware-D.C. Water Science Center, Drought

Community for Data Integration 2020 project report Community for Data Integration 2020 project report

The U.S. Geological Survey Community for Data Integration annually funds small projects focusing on data integration for interdisciplinary research, innovative data management, and demonstration of new technologies. This report provides a summary of the 12 projects funded in fiscal year 2020, outlining their goals, activities, and accomplishments.
Authors
Leslie Hsu, Emily G. Chapin, Theodore B. Barnhart, Amanda E. Cravens, Richard A. Erickson, Jason Ferrante, Aaron Fox, Nathaniel P. Hitt, Margaret Hunter, Katharine Kolb, Jared R. Peacock, Matthew D. Petkewich, Sasha C. Reed, Terry Sohl, Tanja N. Williamson
By
Ecosystems Mission Area, Science Analytics and Synthesis (SAS) Program, Science Synthesis, Analysis, and Research Program, Community for Data Integration (CDI), Fort Collins Science Center, Southwest Biological Science Center, Upper Midwest Environmental Sciences Center, Wetland and Aquatic Research Center

Evaluating distributed snow model resolution and meteorology parameterizations against streamflow observations: Finer Is not always better Evaluating distributed snow model resolution and meteorology parameterizations against streamflow observations: Finer Is not always better

Estimating snow conditions is often done using numerical snowpack evolution models at spatial resolutions of 500 m and greater; however, snow depth in complex terrain often varies on sub-meter scales. This study investigated how the spatial distribution of simulated snow conditions varied across seven model spatial resolutions from 30 to 1,000 m and over two meteorological data sets...
Authors
Theodore B. Barnhart, Annie L. Putman, Aaron Joseph Heldmyer, David M. Rey, John C. Hammond, Jessica M. Driscoll, Graham A. Sexstone
By
Water Resources Mission Area, Maryland-Delaware-D.C. Water Science Center, Colorado Water Science Center, Utah Water Science Center, Wyoming-Montana Water Science Center

High resolution SnowModel simulations reveal future elevation-dependent snow loss and earlier, flashier surface water input for the Upper Colorado River Basin High resolution SnowModel simulations reveal future elevation-dependent snow loss and earlier, flashier surface water input for the Upper Colorado River Basin

Continued climate warming is reducing seasonal snowpacks in the western United States, where >50% of historical water supplies were snowmelt-derived. In the Upper Colorado River Basin, declining snow water equivalent (SWE) and altered surface water input (SWI, rainfall and snowmelt available to enter the soil) timing and magnitude affect streamflow generation and water availability. To...
Authors
John C. Hammond, Graham A. Sexstone, Annie L. Putman, Theodore B. Barnhart, David M. Rey, Jessica M. Driscoll, Glen Liston, Kristen L. Rasmussen, Daniel McGrath, Steven R. Fassnacht, Stephanie K. Kampf
By
Water Resources Mission Area, Maryland-Delaware-D.C. Water Science Center, Colorado Water Science Center, New Mexico Water Science Center, Wyoming-Montana Water Science Center

Non-USGS Publications**

Barnhart, T.B., Vukomanovic, J., Bourgeron, P., and Molotch, N.P. (2021). Future Land Cover and Climate May Drive Decreases inSnow Wind-Scour and Transpiration, Increasing Streamflow at a Colorado, USA Headwater Catchment. Hydrological Processes, e14416.
Barnhart, T. B., Tague, C. L., & Molotch, N. P. (2020). The counteracting effects of snowmelt rate and timing on runoff. Water Resources Research, 56, e2019WR026634.
Barnhart, T.B., N.P. Molotch, B. Livneh, A.A. Harpold, J.F. Knowles, D. Schneider (2016), Snowmelt Rate Dictates Streamflow: Geophysical Research Letters, 43(15), 8006-8016.
Harpold, A.A., J.A. Marshall, S.W. Lyon, T.B. Barnhart, B. Fisher, M. Donovan, K.M. Brubaker, C.J. Crosby, N.F. Glenn, C.L. Glennie, P.B. Kirchner, N. Lam, K.D. Mankoff, J.L. McCreight, N.P. Molotch, K.N. Musselman, J. Pelletier, T. Russo, H. Sangireddy, Y. Sjöberg, T. Swetnam, and N. West (2015), Laser Vision: Lidar as a Transformative Tool to Advance Critical Zone Science: Hydrology and Earth System Science, 19, 2881-2897.
Barnhart, T.B., and B.T. Crosby (2013), Comparing Two Methods of Surface Change Detection on an Evolving Thermokarst Using High-Temporal-Frequency Terrestrial Laser Scanning, Selawik River, Alaska: Remote Sensing, 5, 2813-2837.

**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.

Low Flow Data and Model Discovery Table Low Flow Data and Model Discovery Table

Do you need to know when streamflows are low or if streams go dry? The USGS has developed a Low Flow Data and Model Discovery Table that provides an overview of available data and models with information on streamflow, including low-flow and no-flow conditions.
By
Washington Water Science Center, Wyoming-Montana Water Science Center

Flow-Conditioned Parameter Grid Tools Flow-Conditioned Parameter Grid Tools

The Flow-Conditioned Parameter Grid (FCPG) Tools are a Python 3 library to make FCPGs for either two-digit Hydrologic Unit Code (HUC2) regions, four-digit Hydrologic Unit Code (HUC4) regions, or other geospatial tiling schemes. These tools can be used in a Linux-based high performance computing (HPC) environment or locally on your system.
By
Community for Data Integration (CDI), Wyoming-Montana Water Science Center

StreamStats Data Preparation Tools, version 4 StreamStats Data Preparation Tools, version 4

A Python package to pre-process and hydro-enforce digital elevation models using hydrography features for use in the U.S. Geological Survey (USGS) StreamStats project.
By
Wyoming-Montana Water Science Center
New Open-Source Projects Using NHDPlus

New Open-Source Projects Using NHDPlus

Two new open-source projects, Xstrm and FCPGtools, have been released that provide functionality based on versions of the NHDPlus. Both projects...

Read Article

Science and Products

Tongue River between Tongue River Reservoir and Birney, MT

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving: - a shift in precipitation from snow to rain - changing precipitation intensity and seasonality - increasing atmospheric demand for moisture in mountain river watersheds across the western United States (Seager and others, 2015). These changes will likely alter the timing and quantity of streamflow in rivers draining mountains. The Tongue River flows from the...
By
Water Resources Mission Area, Wyoming-Montana Water Science Center
Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving: - a shift in precipitation from snow to rain - changing precipitation intensity and seasonality - increasing atmospheric demand for moisture in mountain river watersheds across the western United States (Seager and others, 2015). These changes will likely alter the timing and quantity of streamflow in rivers draining mountains. The Tongue River flows from the...
Learn More
Tongue River between Tongue River Reservoir and Birney, MT

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving a shift in precipitation from snow to rain, changing precipitation intensity and seasonality, and increasing atmospheric demand for moisture in mountain river watersheds across the western United States. These changes will likely alter the timing and quantity of streamflow in rivers draining from the mountains. The Tongue River flows from the Bighorn...
By
Climate Adaptation Science Centers
Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Future Streamflow Estimates for Tongue River to Enable Northern Cheyenne Data Driven Water Management and Planning

Atmospheric warming is driving a shift in precipitation from snow to rain, changing precipitation intensity and seasonality, and increasing atmospheric demand for moisture in mountain river watersheds across the western United States. These changes will likely alter the timing and quantity of streamflow in rivers draining from the mountains. The Tongue River flows from the Bighorn mountains in
Learn More
A concrete weir during very low streamflows.

State of the Science in Streamflow Modeling in the North Central Region to Address Partner Needs for Water Availability Under Drought Conditions

Land and water managers often rely on hydrological models to make informed management decisions. Understanding water availability in streams, rivers, and reservoirs during high demand periods that coincide with seasonal low flows can affect how water managers plan for its distribution for human consumption while sustaining aquatic ecosystems. Substantial advancement in hydrological...
By
Climate Adaptation Science Centers
State of the Science in Streamflow Modeling in the North Central Region to Address Partner Needs for Water Availability Under Drought Conditions

State of the Science in Streamflow Modeling in the North Central Region to Address Partner Needs for Water Availability Under Drought Conditions

Land and water managers often rely on hydrological models to make informed management decisions. Understanding water availability in streams, rivers, and reservoirs during high demand periods that coincide with seasonal low flows can affect how water managers plan for its distribution for human consumption while sustaining aquatic ecosystems. Substantial advancement in hydrological modeling has
Learn More
Example FCPG showing stream cells with upstream average annual precipitation.

Flow-Conditioned Parameter Grids

Flow-Conditioned Parameter Grids (FCPGs) are a way of storing the upstream average of datasets, such as precipitation or land cover type, for all points on the landscape.
By
Water Resources Mission Area, Wyoming-Montana Water Science Center
Flow-Conditioned Parameter Grids

Flow-Conditioned Parameter Grids

Flow-Conditioned Parameter Grids (FCPGs) are a way of storing the upstream average of datasets, such as precipitation or land cover type, for all points on the landscape.
Learn More
USGS science for a changing world logo

Building a framework to compute continuous grids of basin characteristics for the conterminous United States

The proposed work will create a seamless pilot dataset of continuous basin characteristics (for example upstream average precipitation, elevation, or dominant land cover type) for the conterminous United States. Basin characteristic data are necessary for training or parameterizing statistical, machine learning, and physical models, and for making predictions across the landscape...
By
Community for Data Integration (CDI)
Building a framework to compute continuous grids of basin characteristics for the conterminous United States

Building a framework to compute continuous grids of basin characteristics for the conterminous United States

The proposed work will create a seamless pilot dataset of continuous basin characteristics (for example upstream average precipitation, elevation, or dominant land cover type) for the conterminous United States. Basin characteristic data are necessary for training or parameterizing statistical, machine learning, and physical models, and for making predictions across the landscape, particularly in
Learn More
Estimated Nitrogen and Phosphorus Input to Fish Creek Watershed

Geospatial Research and Development to Understand Hydrologic Processes

Geospatial Research and Development (GeoRAD) advances understanding of hydrologic processes by using tools and technologies to map, analyze, and visualize water-related data to better understand how water moves and behaves in the environment. Like all natural phenomena, hydrological phenomena occur in specific locations. Remote sensing, GIS, and geostatistical methods are tools that can be used to...
By
Wyoming-Montana Water Science Center
Geospatial Research and Development to Understand Hydrologic Processes

Geospatial Research and Development to Understand Hydrologic Processes

Geospatial Research and Development (GeoRAD) advances understanding of hydrologic processes by using tools and technologies to map, analyze, and visualize water-related data to better understand how water moves and behaves in the environment. Like all natural phenomena, hydrological phenomena occur in specific locations. Remote sensing, GIS, and geostatistical methods are tools that can be used to...
Learn More

Historical simulated snowpack and other hydrometeorology data at 30 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020 Historical simulated snowpack and other hydrometeorology data at 30 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020

This data release contains historical SnowModel (Liston and Elder, 2006) output for the Crown of the Continent and surrounding areas in Montana, USA; and Alberta and British Columbia, Canada from September 1, 1981 through August 31, 2020. Fifteen daily variables were simulated or derived for this release: (1) snow water equivalent (swed), (2) liquid precipitation (rpre), (3) solid...
By
Wyoming-Montana Water Science Center

Historical simulated snowpack and other hydrometeorology data at 90 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020 Historical simulated snowpack and other hydrometeorology data at 90 m for the Crown of the Continent and vicinity, United States and Canada, water years 1981-2020

This data release contains historical SnowModel (Liston and Elder, 2006) output for the Crown of the Continent and surrounding areas in Montana and Idaho, USA; and Alberta and British Columbia, Canada from September 1, 1981 through August 31, 2020. Fifteen daily variables were simulated or derived for this release: (1) snow water equivalent (swed), (2) liquid precipitation (rpre), (3)...
By
Northern Rocky Mountain Science Center

High Resolution Current and Future Climate SnowModel Simulations in the Upper Colorado River Basin High Resolution Current and Future Climate SnowModel Simulations in the Upper Colorado River Basin

This data release contains SnowModel snow evolution simulation output on a 100-meter (m) geospatial grid for a 311 kilometer (km) × 300 km model domain in Colorado, United States, encompassing the Colorado and Gunnison River Basin headwaters in the Upper Colorado River Basin. Weather Research and Forecasting (WRF) Model convection-permitting and orography-resolving (4-km grid spacing)...
By
Colorado Water Science Center

Basin Characteristics and Streamflow Statistics for Selected Gages, Alaska, USA (ver. 2.0, September, 2022) Basin Characteristics and Streamflow Statistics for Selected Gages, Alaska, USA (ver. 2.0, September, 2022)

This data release documents the data used for the associated publication "Evaluating hydrologic region assignment techniques for ungaged watersheds in Alaska, USA" (Barnhart and others, 2022) The data sets within this release are stored in 14 files: (1) Streamflow observations and sites used. (2) Statistically estimated streamflow values computed for each site. (3) Streamflow statistics...
By
Wyoming-Montana Water Science Center

Historical simulated snowpack for the Lake Sherburne, MT watershed and vicinity, water years 1980-2019 Historical simulated snowpack for the Lake Sherburne, MT watershed and vicinity, water years 1980-2019

Abstract This data release contains historical SnowModel (Liston and Elder, 2006) output for the Lake Sherburne, MT watershed and surrounding area. The two quantities simulated for this release were snow water equivalent depth (swed), the liquid water equivalent depth stored as snow in the simulation domain, and runoff (roff), which includes snowmelt at the snow-soil interface and...
By
Wyoming-Montana Water Science Center

Flow-Conditioned Parameter Grids for the Contiguous United States: A Pilot, Seamless Basin Characteristic Dataset Flow-Conditioned Parameter Grids for the Contiguous United States: A Pilot, Seamless Basin Characteristic Dataset

Abstract To aid in parameterization of mechanistic, statistical, and machine learning models of hydrologic systems in the contiguous United States (CONUS), flow-conditioned parameter grids (FCPGs) have been generated describing upstream basin mean elevation, slope, land cover class, latitude, and 30-year climatologies of mean total annual precipitation, minimum daily air temperature, and...
By
Community for Data Integration (CDI), Wyoming-Montana Water Science Center
No results found.
Filter Total Items: 13

Fine-resolution satellite remote sensing improves spatially distributed snow modeling to near real time Fine-resolution satellite remote sensing improves spatially distributed snow modeling to near real time

Given the highly variable distribution of seasonal snowpacks in complex mountainous environments, the accurate snow modeling of basin-wide snow water equivalent (SWE) requires a spatially distributed approach at a sufficiently fine grid resolution (
Authors
Graham A. Sexstone, Garrett Alexander Akie, David J. Selkowitz, Theodore B. Barnhart, David M. Rey, Claudia León-Salazar, Emily Carbone, Lindsay A. Bearup
By
Water Resources Mission Area, Colorado Water Science Center, Wyoming-Montana Water Science Center

Cryospheric sciences at the U.S. Geological Survey Cryospheric sciences at the U.S. Geological Survey

Introduction The cryosphere is the collective parts of the Earth where water is in its frozen state and includes snow, glaciers, ice sheets, ice shelves, freshwater ice, sea ice, and permafrost. The cryosphere is a climate indicator and climate regulator. Surface cryosphere features, such as glaciers, snow, and sea ice, store freshwater and make the surface of the Earth bright white...
Authors
Caitlyn Florentine, Erich H. Peitzsch, Miriam C. Jones, Theodore B. Barnhart, Thomas M. Cronin
By
Ecosystems Mission Area, Northern Rocky Mountain Science Center

Streamflow timing and magnitude during snow drought depend on snow drought type and regional hydroclimate Streamflow timing and magnitude during snow drought depend on snow drought type and regional hydroclimate

Communities around the world rely on snowmelt to meet water demands, and periods of lower than normal snow accumulation, snow droughts, can decrease water supplies. Leveraging 172 minimally disturbed and seasonally snow-covered watersheds, we developed an approach to examine the effects of cool & dry, warm & dry, and warm & wet snow droughts on streamflow timing and magnitude by...
Authors
John C. Hammond, Annie L. Putman, Theodore B. Barnhart, Graham A. Sexstone, Gregory J. McCabe, David M. Wolock, Aaron Joseph Heldmyer, Stephanie K. Kampf
By
Maryland-Delaware-D.C. Water Science Center, Drought

Community for Data Integration 2020 project report Community for Data Integration 2020 project report

The U.S. Geological Survey Community for Data Integration annually funds small projects focusing on data integration for interdisciplinary research, innovative data management, and demonstration of new technologies. This report provides a summary of the 12 projects funded in fiscal year 2020, outlining their goals, activities, and accomplishments.
Authors
Leslie Hsu, Emily G. Chapin, Theodore B. Barnhart, Amanda E. Cravens, Richard A. Erickson, Jason Ferrante, Aaron Fox, Nathaniel P. Hitt, Margaret Hunter, Katharine Kolb, Jared R. Peacock, Matthew D. Petkewich, Sasha C. Reed, Terry Sohl, Tanja N. Williamson
By
Ecosystems Mission Area, Science Analytics and Synthesis (SAS) Program, Science Synthesis, Analysis, and Research Program, Community for Data Integration (CDI), Fort Collins Science Center, Southwest Biological Science Center, Upper Midwest Environmental Sciences Center, Wetland and Aquatic Research Center

Evaluating distributed snow model resolution and meteorology parameterizations against streamflow observations: Finer Is not always better Evaluating distributed snow model resolution and meteorology parameterizations against streamflow observations: Finer Is not always better

Estimating snow conditions is often done using numerical snowpack evolution models at spatial resolutions of 500 m and greater; however, snow depth in complex terrain often varies on sub-meter scales. This study investigated how the spatial distribution of simulated snow conditions varied across seven model spatial resolutions from 30 to 1,000 m and over two meteorological data sets...
Authors
Theodore B. Barnhart, Annie L. Putman, Aaron Joseph Heldmyer, David M. Rey, John C. Hammond, Jessica M. Driscoll, Graham A. Sexstone
By
Water Resources Mission Area, Maryland-Delaware-D.C. Water Science Center, Colorado Water Science Center, Utah Water Science Center, Wyoming-Montana Water Science Center

High resolution SnowModel simulations reveal future elevation-dependent snow loss and earlier, flashier surface water input for the Upper Colorado River Basin High resolution SnowModel simulations reveal future elevation-dependent snow loss and earlier, flashier surface water input for the Upper Colorado River Basin

Continued climate warming is reducing seasonal snowpacks in the western United States, where >50% of historical water supplies were snowmelt-derived. In the Upper Colorado River Basin, declining snow water equivalent (SWE) and altered surface water input (SWI, rainfall and snowmelt available to enter the soil) timing and magnitude affect streamflow generation and water availability. To...
Authors
John C. Hammond, Graham A. Sexstone, Annie L. Putman, Theodore B. Barnhart, David M. Rey, Jessica M. Driscoll, Glen Liston, Kristen L. Rasmussen, Daniel McGrath, Steven R. Fassnacht, Stephanie K. Kampf
By
Water Resources Mission Area, Maryland-Delaware-D.C. Water Science Center, Colorado Water Science Center, New Mexico Water Science Center, Wyoming-Montana Water Science Center

Non-USGS Publications**

Barnhart, T.B., Vukomanovic, J., Bourgeron, P., and Molotch, N.P. (2021). Future Land Cover and Climate May Drive Decreases inSnow Wind-Scour and Transpiration, Increasing Streamflow at a Colorado, USA Headwater Catchment. Hydrological Processes, e14416.
Barnhart, T. B., Tague, C. L., & Molotch, N. P. (2020). The counteracting effects of snowmelt rate and timing on runoff. Water Resources Research, 56, e2019WR026634.
Barnhart, T.B., N.P. Molotch, B. Livneh, A.A. Harpold, J.F. Knowles, D. Schneider (2016), Snowmelt Rate Dictates Streamflow: Geophysical Research Letters, 43(15), 8006-8016.
Harpold, A.A., J.A. Marshall, S.W. Lyon, T.B. Barnhart, B. Fisher, M. Donovan, K.M. Brubaker, C.J. Crosby, N.F. Glenn, C.L. Glennie, P.B. Kirchner, N. Lam, K.D. Mankoff, J.L. McCreight, N.P. Molotch, K.N. Musselman, J. Pelletier, T. Russo, H. Sangireddy, Y. Sjöberg, T. Swetnam, and N. West (2015), Laser Vision: Lidar as a Transformative Tool to Advance Critical Zone Science: Hydrology and Earth System Science, 19, 2881-2897.
Barnhart, T.B., and B.T. Crosby (2013), Comparing Two Methods of Surface Change Detection on an Evolving Thermokarst Using High-Temporal-Frequency Terrestrial Laser Scanning, Selawik River, Alaska: Remote Sensing, 5, 2813-2837.

**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.

Low Flow Data and Model Discovery Table Low Flow Data and Model Discovery Table

Do you need to know when streamflows are low or if streams go dry? The USGS has developed a Low Flow Data and Model Discovery Table that provides an overview of available data and models with information on streamflow, including low-flow and no-flow conditions.
By
Washington Water Science Center, Wyoming-Montana Water Science Center

Flow-Conditioned Parameter Grid Tools Flow-Conditioned Parameter Grid Tools

The Flow-Conditioned Parameter Grid (FCPG) Tools are a Python 3 library to make FCPGs for either two-digit Hydrologic Unit Code (HUC2) regions, four-digit Hydrologic Unit Code (HUC4) regions, or other geospatial tiling schemes. These tools can be used in a Linux-based high performance computing (HPC) environment or locally on your system.
By
Community for Data Integration (CDI), Wyoming-Montana Water Science Center

StreamStats Data Preparation Tools, version 4 StreamStats Data Preparation Tools, version 4

A Python package to pre-process and hydro-enforce digital elevation models using hydrography features for use in the U.S. Geological Survey (USGS) StreamStats project.
By
Wyoming-Montana Water Science Center
New Open-Source Projects Using NHDPlus

New Open-Source Projects Using NHDPlus

Two new open-source projects, Xstrm and FCPGtools, have been released that provide functionality based on versions of the NHDPlus. Both projects...

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*Disclaimer: Listing outside positions with professional scientific organizations on this Staff Profile are for informational purposes only and do not constitute an endorsement of those professional scientific organizations or their activities by the USGS, Department of the Interior, or U.S. Government

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