Simple Time-Power Functions for Rainwater Infiltration and Runoff

Dixon, R. M., Simanton, J. R., Lane, L. J.

15 April 1978

From the Proceedings of the 1978 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 14-15, 1978, Flagstaff, Arizona / The equations of Darcy, Kostiakov, Ostashev, Philip, and four modified Philip equations were evaluated for use in predicting and controlling rainwater infiltration and rainfall excess in crop and rangelands. These eight equations were least- square fitted to data from ring, border-irrigation, closed-top, and sprinkling infiltrometers. Kostiakov's equation satisfied the evaluation criteria better than the other seven equations. The parameters of Kostiakov's equation were physically interpreted by relating their magnitudes to some physical, biological, and hydraulic characteristics of the infiltration system. These characteristics included several infiltration abatement and augmentation processes and factors that are controlled at the soil surface by land management practices. The eight equations were also fitted to rainfall data to permit calculating runoff from small surface areas about the size of a typical crop plant. Comparison of the regression curves for infiltration and rainfall suggested that land management practices that appropriately alter the soil surface will permit wide-range control of infiltration, runoff, and erosion; and thereby achieve conservation and more efficient use of soil and water resources for crop production. The most important soil surface conditions affecting infiltration were microroughness, macroporosity, plant litter, and effective surface head.

Hydrology -- Arizona.

Water resources development -- Arizona.

Hydrology -- Southwestern states.

Infiltration

Rainfall-runoff relationships

Runoff

Runoff forecasting

Soil water movement

Infiltrometers

Irrigation practices

Rain water

Rainfall disposition

Air-earth interfaces

Equations

Forecasting

Regression analysis

Erosion

Regional Differences in Runoff-Producing Thunderstorms Rainfall in the Southwest

Osborn, H. B.

23 April 1971

From the Proceedings of the 1971 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 22-23, 1971, Tempe, Arizona / Quantitative descriptions of regional differences of rainfall amounts and intensities in the southwest, such as depth-duration frequencies, generally have ignored differences in the storm system that generated the rainfall and have lumped essentially different storm systems together. Thunderstorm rainfall in southern Arizona and New Mexico were analyzed using data from both recording and standard rain gages. The results were somewhat conflicting. Possibly because of more frontal activity and less distance from the Gulf of Mexico., the thunderstorms in eastern New Mexico can be more intense than those in southeastern Arizona. Recording rain gage records suggest that air-mass thunderstorms produce a larger number of more intense short-duration (about 1 hour or less) rains in southeastern Arizona than in other parts of southern Arizona. However, standard rain gage records from southern Arizona indicate that rainfall from individual air-mass thunderstorms may be greater in south-central Arizona than in se or sw Arizona. But frequency analysis of standard gage data from air-mass storms shows that the 100-year point rainfall is about 3 inches in all 3 regions. With more data becoming available, especially from remote areas, more exact separation of thunderstorm types and a better definition of rainfall will soon be possible.

Water resources development -- Arizona.

Hydrology -- Arizona.

Hydrology -- Southwestern states.

Thunderstorms

Rainfall

Rain gages

Storm structure

Southwest U.S.

Arizona

New Mexico

Arid lands

Climatic data

Air masses

Convection

Rainfall disposition

Rainfall intensity

Depth-area-duration analysis

Distribution patterns

Recording rain gages

A Proposed Model for Flood Routing in Abstracting Ephemeral Channels

Lane, Leonard J.

06 May 1972

From the Proceedings of the 1972 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - May 5-6, 1972, Prescott, Arizona / Almost all runoff from semiarid rangeland watersheds in southern Arizona results from intense highly variable thunderstorm rainfall. Abstractions, or transmission losses, are important in diminishing streamflow, supporting riparian vegetation and providing natural groundwater recharge. A flood routing procedure is developed using data from the walnut gulch experimental watershed, where flood movement and transmission losses are represented by a system using storage in the channel reach as a state variable which determines loss rates. Abstractions are computed as a cascade of general components in linear form. Wide variation in the parameters of this linear model with increasing inflow indicates that a linear relation between losses and storage is probably incorrect for ephemeral channels.

Hydrology -- Arizona.

Water resources development -- Arizona.

Hydrology -- Southwestern states.

Model studies

Flood routing

Flood forecasting

Ephemeral streams

Rainfall disposition

Rainfall-runoff relationships

Watershed management

Range management

Thunderstorms

Rainfall

Streamflow

Vegetation

Groundwater recharge

Bank storage

Rates

Storage

Arizona

Water Disposition in Ephemeral Stream Channels

Sammis, T. W.

06 May 1972

From the Proceedings of the 1972 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - May 5-6, 1972, Prescott, Arizona / The contribution of flows from small watersheds to groundwater recharge is of interest. Water disposition depends on infiltration and evaporation characteristics. This study had the objective of developing an infiltration equation for estimating transmission losses during a flow event in an ephemeral stream near Tucson, Arizona, in the rocky mountain forest and range experiment station. Palo Verde, desert hackberry, cholla, marmontea and mesquite are the major bank species of the sandy channels. A climatic section consisting of a hydrothermograph recording rain gage and class a evaporation pan was installed. A water balance method was used to estimate evapotranspiration. A specially designed infiltrometer was used to simulate flow events. The data allowed the following conclusions: Philip's infiltration equation is an excellent mathematical model, initial moisture affects initial infiltration rate, the Philip coefficients are determinable by the infiltrometer constructed, soil moisture affects infiltration rates, and transpiration rates diminish linearly proportional to the ratio of available water to field capacity.

Hydrology -- Arizona.

Water resources development -- Arizona.

Hydrology -- Southwestern states.

Rainfall disposition

Ephemeral streams

Groundwater recharge

Infiltration

Evapotranspiration

Equations

Forecasting

Vegetation

Channels

Climates

Evaporation

Instrumentation

Infiltrometers

Simulation analysis

Soil structure

Field capacity

Arizona

Arid lands

Riparian plants

Transmission losses

Philip's equation

Simulation of Summer Rainfall Occurrence in Arizona and New Mexico

Yakowitz, Sidney

16 April 1977

From the Proceedings of the 1977 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 15-16, 1977, Las Vegas, Nevada / Thunderstorms produce most of the annual rainfall and almost all runoff from arid and semiarid rangelands in the southwest U.S. A model was developed to be used for predicting runoff in river basins, flood plane zonings, estimating flood damage, erosion, and sediment transport, and estimating precipitation available for forage growth. This rainfall occurrence model has three parameters: elevation, latitude and longitude, and takes into account rainfall occurrence in 22 stations located in Arizona and New Mexico. From these variables, mathematical equations were developed in an effort to predict point rainfall occurrence. Estimates of the number of seasonal occurrences were used as a check of the equations within the model.

Hydrology -- Arizona.

Water resources development -- Arizona.

Hydrology -- Southwestern states.

Precipitation (atmospheric)

Mathematical models

Statistical models

Simulated rainfall

Runoff

Arizona

New Mexico

Distribution studies

Flood forecasting

Summer

Maximum probable flood

Rainfall intensity

Impact (rainfall)

Forecasting

Thunderstorms

Rainfall disposition

Floods

Markov processes