5.5: Infiltration Versus Runoff

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Page ID: 25130

Fred Magdoff & Harold van Es
University of Vermont & Cornell University via Sustainable Agriculture Research and Education (SARE) program

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An important function of soil is to absorb water at the land surface and either store it for use by plants or slowly release it to groundwater through gravitational flow (Figure 5.8). When rainfall hits the ground, most water will infiltrate the soil, but under certain conditions it may run off the surface or stand in ruts or depressions before infiltrating or evaporating. The maximum amount of rainwater that can enter a soil in a given time, called infiltration capacity, is influenced by the soil type (large pores result in higher capacity), structure and moisture content at the start of the rain.

how soil infiltration differs diagram — Figure 5.8. The infiltration capacity of the soil determines whether water infiltrates or runs off the surface. *Illustration by Vic Kulihin.*

If rain is very gentle, the infiltration capacity is generally not exceeded and all precipitation enters the soil. Even in an intense storm, water initially enters a soil readily as it is literally sucked into the dry ground. But as the soil wets up during a continuing intense storm, water entry into the soil is reduced and a portion of rainfall may begin to run downhill over the surface to a nearby stream or wetland. The ability of a soil to maintain high infiltration rates, even when saturated, is related to the sizes of its pores. Since sandy and gravelly soils have more large pores, they maintain better infiltration during a storm than fine loams and clays. But soil aggregation is also important in governing the number of pores and their sizes: When finer-textured soils have strong aggregates due to good management, they can also maintain high infiltration rates. But this is not the case when those aggregates fail and the soil becomes compacted.

Runoff is produced when rainfall exceeds a soil’s infiltration capacity. Rainfall or snowmelt on frozen ground generally poses even greater runoff concerns, as pores are blocked with ice. Runoff happens more readily with poorly managed soils because they lack strong aggregates that hold together against the force of raindrops and moving water and, therefore, have few large pores open to the surface to quickly conduct water downward. Such runoff can initiate erosion, with losses of nutrients and agrochemicals as well as sediment.

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