United States Environmental Protection Agency	Office of Research and Development

National Exposure Research Laboratory
Research Abstract

Government Performance Results Act (GPRA) Goal #4.5.2
Annual Performance Measure #251

Significant Research Findings:

Comparisons of Hydrologic Responses at Different Watershed Scales

Land surface hydrology controls runoff production and transport of sediments
and nutrients from upland and hillslope areas to streams and other water
bodies. In general, landscape characteristics such as soil, geology, land use and
land cover, and topography of a watershed influence hydrologic responses.
Knowing the relationships between landscape characteristics and hydrologic
responses would enable decision makers to select watershed management
practices that target specific landscape characteristics. The basis of the
underlying scientific problem that this study attempts to answer is what
controls the hydrologic response of a watershed and why watersheds respond
differently to climatic inputs. Other equally important hydrologic response
related questions include what constitutes a hydrologic response of a watershed
and how best can it be represented.

The objectives of this study are: (1) to identify the dominant landscape
descriptors that control the hydrologic responses of the Mid-Atlantic
watersheds; (2) to develop relationships between landscape-climate descriptors
and hydrologic response descriptors; and (3) to compare the hydrologic
responses of the Mid-Atlantic watersheds. To achieve these objectives, a
number of approaches were used.

•	Selection of representative watersheds from the Mid-Atlantic Region

•	Collection of landscape (e.g., soil, geology, land use and land cover,
and topography), climate, and hydrologic response descriptor data from
watersheds located in the Appalachian Plateau, Ridge and Valley, Blue
Ridge, and Piedmont Physiographic Provinces.

•	Development of landscape-climate and hydrologic response
relationships using multiple regression analysis.

•	Comparisons of hydrologic responses of the Mid-Atlantic watersheds at
different spatial and temporal scales using a water balance approach and
a flow duration curve statistical approach.

Results and The findings of this research can be summarized as follow:

Impact

•	The hydrologic responses of the Mid-Atlantic watersheds were strongly
influenced by elevation and latitudinal position of a watershed within
the region. As a result, mountainous watersheds in the Appalachian
Plateau and the ridge-dominated Ridge and Valley Provinces had higher

Scientific
Problem and
Policy Issues

Research
Approach

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seasonal variability in hydrologic responses than watersheds located in
the Piedmont and the valley-dominated Ridge and Valley Provinces.
Snowmelt runoff which is dependent on elevation and latitudinal
position was the main source of seasonal variability in streamflow.
The Appalachian Plateau and the Ridge and Valley watersheds had the
lowest sustained low flows and thus the highest vulnerability to
droughts. By contrast, the Piedmont watersheds had the highest
sustained low flows and therefore had the lowest vulnerability to
droughts.

At the regional spatial scale and multi-year temporal scale, dryness
index, a climate descriptor, was the best hydrologic response predictor
for high flow conditions ( Q1 to Q50). For low flow conditions (Q70 to
Q95), however, baseflow index which is a surrogate geology descriptor
was the best hydrologic response predictor.

At the physiographic province spatial scale and annual time scale, mean
monthly rainfall, dryness index, and baseflow index were the best
hydrologic response predictors for the Ridge and Valley Physiographic
Province. For the Appalachian Plateau watersheds, the mean monthly
December precipitation was the best hydrologic response predictor
whereas April, June, July, and August mean monthly precipitation and
soil moisture storage capacity were the best hydrologic response
predictors.

Soil descriptors such as soil texture classes, bulk density, soil depth, and
saturated hydraulic conductivity of the top two soil layers were the
second best hydrologic response predictors across different flow
conditions. Other important hydrologic response predictors included
drainage density, relief ratio, channel slope, and median watershed
slope.

Future	The method developed herein has a potential for identification of hydrologic

Research model parameters, testing existing hydrologic models, and the development of
new hydrologic models that have strong physical basis and less parameters than
those currently available. Additional research that extends the landscape-
climate and hydrologic response relationships presented herein to relationships
between hydrologic responses and pollutant loads are needed.

Information

Contacts for	Questions and inquiries regarding this research can be directed to:

Additional Yusuf Mohamoud, Ph.D., P.E.

National Exposure Research Laboratory
Ecosystem Assessment Branch
960 College Station Road
Athens, GA 30605
Tel 706-355-8109
e-mail: mohamoud.vusuf@epa.gov

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