Presentation is loading. Please wait.

Presentation is loading. Please wait.

Great Valley Water Resources Science Forum

Published byBerniece Berry Modified over 8 years ago

Similar presentations

Presentation on theme: "Great Valley Water Resources Science Forum"— Presentation transcript:

1 Great Valley Water Resources Science Forum
GSFLOW Coupled Groundwater/Surface-Water Model: Background and Possible Applications in the Great Valley Great Valley Water Resources Science Forum October 7, 2009

2 Why was GSFLOW developed?
To improve our ability to simulate and understand Watershed hydrologic processes and water availability Links between hydrologic processes and climate, vegetation, land uses, water-supply development, and ecology

3 Uses of GSFLOW Determine flow rates and storage volumes of water throughout a watershed—from the tree canopy to deep aquifers: Evaporation and plant transpiration Soil infiltration and interflow Snowpack generation and depletion Groundwater recharge Streamflow generation

4 Components of Streamflow for a Year of Below-Average Precipitation, Sagehen Creek, Truckee, CA

5 Uses of GSFLOW Simulate both low-flow (baseflow and drought) and high-flow (storm) conditions within a watershed

6 Uses of GSFLOW Simulate hydrologic response to changing land uses, population growth, and possible future climate conditions 16 19 22 25 28 2001 2007 2013 2019 2025 2031 2037 2043 2049 2055 2061 2067 2073 2079 2085 2091 2097 Maximum Temperature, degrees C Projected average maximum daily temperature, Tahoe Basin, California and Nevada

7 What is GSFLOW? A Basin-Scale Model Based on the USGS PRMS Watershed Model and MODFLOW Groundwater Flow Model

8 Enhanced Modeling Capabilities Developed for GSFLOW
Unsaturated-zone flow below soils, streams, and lakes Flow, storage, and ET in the unsaturated zone and recharge to the water table in response to infiltration at land surface

9 Enhanced Modeling Capabilities Developed for GSFLOW
Enhanced soil-zone dynamics (capillary, gravity-flow, and preferential-flow reservoirs) Enhanced streamflow simulation

10 Some of the Hydrologic Processes Simulated
Potential ET Canopy interception Snowpack accumulation, melting, sublimation Surface-water runoff Interflow Infiltration to soil zone ET within soil zone 1-D Unsaturated-zone flow, storage, and ET 3-D Groundwater flow Streamflow Lakes

11 Climatic and Hydrologic Drivers
Precipitation Air Temperature Solar radiation Groundwater withdrawals Groundwater flow and water-level conditions along boundary of simulated area

12 Spatial Discretization—PRMS hydrologic response units (HRUs) are intersected with MODFLOW finite-difference cells Sagehen Creek watershed, Truckee, CA

13 Some Important Design Criteria for GSFLOW Development
Calculate and provide detailed water-budget information for the various hydrologic processes in both space and time Ensure that the model conserves mass Allow simulations using only PRMS or MODFLOW to facilitate initial calibration of model parameters prior to a full GSFLOW (coupled-model) simulation

14 Initial GSFLOW Applications by the USGS
Trout Lake Watershed, WI Black Earth Creek Watershed, WI Spring Creek Watershed, PA Incline Basin near Lake Tahoe, Nevada Walker Lake Watershed, NV Santa Rosa Plain, northern CA Rialto-Colton Basin, southern CA

15 Possible Applications in the Great Valley

16 Opequon Creek Watershed
Link the transient groundwater-flow model of Opequon Creek watershed with a PRMS model Opequon Creek

17 Benefits Improved representation of hydrologic processes in the watershed and links among land-surface, subsurface, and surface-water hydrologic systems Improved water budgets throughout all hydrologic components of the watershed

18 Data Considerations Climate inputs: Land-surface processes:
Daily precipitation and air-temperature data Land-surface processes: Evapotranspiration Canopy interception Snowpack dynamics Surface runoff Soil-zone processes

19 Data Considerations Streamflow and Springs Subsurface processes:
Unsaturated-zone flow Groundwater flow, including wells

20 Discretization of Watershed: PRMS HRUs could be coincident with MODFLOW cells, but not required

21 Calibration Considerations
A multistep process: PRMS transient (daily) calibration MODFLOW steady-state calibration Coupled GSFLOW transient (daily) calibration Calibration data: Streamflow Groundwater levels

22 GSFLOW Code and Documentation Report Available online:
USGS Water Resources Groundwater Software webpage

23 Questions?

Download ppt "Great Valley Water Resources Science Forum"

Similar presentations

The Drainage Basin System

The Drainage Basin System
Watershed Hydrology, a Hawaiian Prospective: Evapotranspiration Ali Fares, PhD Evaluation of Natural Resource Management, NREM 600 UHM-CTAHR-NREM.

Watershed Hydrology, a Hawaiian Prospective: Evapotranspiration Ali Fares, PhD Evaluation of Natural Resource Management, NREM 600 UHM-CTAHR-NREM.
Sacramento Soil Moisture Accounting Model (SAC-SMA)

Sacramento Soil Moisture Accounting Model (SAC-SMA)
Runoff and Streamflow P Q

Runoff and Streamflow P Q
Runoff Processes Daene C. McKinney

Runoff Processes Daene C. McKinney
1 Hydrologic Cycle is the never ending cyclic exchange of water

1 Hydrologic Cycle is the never ending cyclic exchange of water
Hydrologic Abstractions

Hydrologic Abstractions
The Water Cycle.

The Water Cycle.
Hydrology The flow of water across and through near surface environments.

Hydrology The flow of water across and through near surface environments.
Surface Water (Lakes, streams, ponds, wetlands, etc.)

Surface Water (Lakes, streams, ponds, wetlands, etc.)
Surface Water Simulation Group. Comprehensive watershed scale model developed and supported by the USDA-ARS capable of simulating surface and groundwater.

Surface Water Simulation Group. Comprehensive watershed scale model developed and supported by the USDA-ARS capable of simulating surface and groundwater.
Engineering Hydrology (ECIV 4323)

Engineering Hydrology (ECIV 4323)
Hydrology and Water Resources Civil and Environmental Engineering Dept. Physically-based Distributed Hydrologic Modeling.

Hydrology and Water Resources Civil and Environmental Engineering Dept. Physically-based Distributed Hydrologic Modeling.
FLUVIAL PROCESSES J. David Rogers. Part 1 THE WATER CYCLE and WATER BALANCE.

FLUVIAL PROCESSES J. David Rogers. Part 1 THE WATER CYCLE and WATER BALANCE.
A Discussion of Groundwater Modeling and Climate Change By Leslie Llado.

A Discussion of Groundwater Modeling and Climate Change By Leslie Llado.
ESS 454 Hydrogeology Module 1 Course Overview, Hydrogeology History,

ESS 454 Hydrogeology Module 1 Course Overview, Hydrogeology History,
EEOS 350: Quantitative hydrogeology Lecture 2 Water balance.

EEOS 350: Quantitative hydrogeology Lecture 2 Water balance.
Applying Methods for Assessing the Costs and Benefits of CCA 2 nd Regional Training Agenda, 30 September – 4 October 2013 Priyanka Dissanayake- Regional.

Applying Methods for Assessing the Costs and Benefits of CCA 2 nd Regional Training Agenda, 30 September – 4 October 2013 Priyanka Dissanayake- Regional.
WaterSmart, Reston, VA, August 1-2, 2011 Steve Markstrom and Lauren Hay National Research Program Denver, CO Jacob LaFontaine GA Water.

WaterSmart, Reston, VA, August 1-2, 2011 Steve Markstrom and Lauren Hay National Research Program Denver, CO Jacob LaFontaine GA Water.
Integrated Water Management Modeling Framework in Nebraska Association of Western State Engineers Spring Workshop Salt Lake City, Utah June 9, 2015 Mahesh.

Integrated Water Management Modeling Framework in Nebraska Association of Western State Engineers Spring Workshop Salt Lake City, Utah June 9, 2015 Mahesh.

Similar presentations

Ads by Google