Infiltration and Runoff from Terrestrial Hydrology Models

Objectives

Hydrologic modeling within SRBEX is concerned with the interaction and behavior of the hydrologic cycle as it pertains to the land surface. To this end, we seek to develop a terrestrial hydrology model (THM) capable of realistically simulating the response of watersheds of diverse sizes to storm events.

Current Activities

The initial thrust of this effort has been twofold:

Examining available soils and landcover datasets to determine their suitability for determining runoff curve numbers, and
Developing, calibrating, and integrating the overland flow and channel routing components of the THM.

Several soils and landuse/landcover classification databases have been investigated for their potential value in estimating hydrologic abstractions such as runoff curve number. The STATSGO soils database includes information such as soil-texture class, hydrologic soil group, available water capacity, and permeability. The STATSGO saturated permeability values, which may represent laboratory rather than field measurements, are very high compared to those normally used for hydrologic modeling; as an interim measure, each STATSGO soil type is being assigned a permeability obtained from other sources. The higher resolution SSURGO (Soil Survey Geographic) database is being examined as an alternative source of soils information; unfortunately, these data have been digitized for only a few counties within the Susquehanna River Basin. In particular, SSURGO data have been combined with the 25-meter EPA EMAP landuse/landcover data to estimate curve numbers for the Mahantango Creek basin and the WE-38 intensive study area within it.

The current version of the THM estimates rainfall infiltration and, ultimately, runoff by one of 3 methods: a phi-index or constant infiltration routine, the SCS curve number method, or the Green-Ampt equation. It approximates overland flow using the forward finite difference solution to the kinematic wave equation, and incorporates a modified Muskingum channel routing routine. Groundwater, reservoir, and snowmelt components will be added later.

In addition to testing and calibration, current model development and research focus on stabilizing the channel routing scheme, determining the sensitivity of the rainfall network requirements, and investigating the applicability of the three alternative infiltration methods.

Results

The THM has been run for several rainfall events in the WE-38 intensive study area, using observed precipitation data, with very good results. Hydrograph peaks, which are obviously the result of the immediate response of overland flow, are matched quite well. Hydrograph volumes are matched reasonably well, particularly when there is an attempt to account for baseflow contributions. There is need to enhance this aspect of the model, as the current THM does not contain a groundwater or through-flow component.

A comparison of runoff hydrographs predicted using the Green-Ampt equation and using Philip's equation with actual stream gage data (Lukhele, 1994) concluded that Green-Ampt performed better than Philip's equation. Specifically, the Green-Ampt method is better able to account for precipitation and infiltration under variable rainfall intensities.

Last change: 8 May 1995, R. A. White / raw@essc.psu.edu