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Jensen Jensen, Haise Haise (1963)
Estimating evapotranspiration from solar radiationJ. Irrig. Drain. Div. Amer. Soc. Civil Eng., 89
T. Black, W. Gardner, G. Thurtell (1969)
The Prediction of Evaporation, Drainage, and Soil Water Storage for a Bare SoilSoil Science Society of America Journal, 33
Allen (1964)
253Agron. J., 56
Black (1970)
66Agron. J., 62
O. Denmead, L. Fritschen, R. Shaw (1962)
Spatial Distribution of Net Radiation in a Corn Field1Agronomy Journal, 54
H. Penman (1963)
Vegetation and hydrology
Denmead (1962)
505Agron. J., 53
Criddle (1958)
1J. Irrig. Drain. Div. Amer. Soc. Civil Eng., 84
LaRue (1968)
625Argon. J., 60
J. Ritchie, E. Burnett (1971)
Dryland Evaporative Flux in a Subhumid Climate: II. Plant Influences1Agronomy Journal, 63
Jensen (1969)
25J. Irrig. Drain. Div. Amer. Soc. Civil Eng., 96
Criddle Criddle (1958)
Methods of computing consumptive use of waterJ. Irrig. Drain. Div. Amer. Soc. Civil Eng., 84
H. Blaney (1959)
Monthly Consumptive Use Requirements for Irrigated CropsJournal of the Irrigation and Drainage Division, 85
L. Brun, E. Kanemasu, W. Powers (1972)
Evapotranspiration from Soybean and Sorghum Fileds1Agronomy Journal, 64
L. Allen, C. Yocum, E. Lemon (1964)
Photosynthesis Under Field Conditions. VII. Radiant Energy Exchanges Within a Corn Crop Canopy and Implications in Water Use Efficiency1Agronomy Journal, 56
T. Black, C. Tanner, W. Gardner (1970)
Evapotranspiration from a Snap Bean Crop1Agronomy Journal, 62
Jensen Jensen, Robb Robb, Franzoy Franzoy (1969)
Scheduling irrigations using climate?crop?soil dataJ. Irrig. Drain. Div. Amer. Soc. Civil Eng., 96
W. Gardner, D. Hillel (1962)
The relation of external evaporative conditions to the drying of soilsJournal of Geophysical Research, 67
Penman (1956)
9Neth. J. Agr. Sci., 4
Blaney Blaney (1959)
Monthly consumptive use requirements for irrigated cropsJ. Irrig. Drain. Div. Amer. Soc. Civil Eng., 85
Jensen (1963)
15J. Irrig. Drain. Div. Amer. Soc. Civil Eng., 89
Bavel Bavel, Stirk Stirk, Brust Brust (1968)
Hydraulic properties of a clay loam soil and the field measurement of water uptake by roots, 1, Interpretation of water content and pressure profilesSoil Sci. Soc. Amer. Proc., 32
Gardner (1962)
4319J. Geophys. Res., 67
J. Ritchie, E. Burnett, R. Henderson (1972)
Dryland Evaporative Flux in a Subhumid Climate: III. Soil Water Influence1Agronomy Journal, 64
LaRue LaRue, Nielsen Nielsen, Hagan Hagan (1968)
Soil water flux below a ryegrass root zoneArgon. J., 60
W. Criddle (1958)
Methods of Computing Consumptive Use of WaterJournal of the Irrigation and Drainage Division, 84
Brun (1972)
145Agron. J., 64
Monteith (1965)
345J. Appl. Ecol., 2
Black Black, Gardner Gardner, Thurtell Thurtell (1969)
The prediction of evaporation, drainage, and soil water storage for a bare soilSoil Sci. Soc. Amer. Proc., 33
H. Penman (1956)
Evaporation: an introductory surveyNetherlands Journal of Agricultural Science, 4
J. Ritchie (1971)
Dryland Evaporative Flux in a Subhumid Climate: I. Micrometeorological Influences1Agronomy Journal, 63
J. Monteith, G. Szeicz, P. Waggoner (1965)
THE MEASUREMENT AND CONTROL OF STOMATAL RESISTANCE IN THE FIELDJournal of Applied Ecology, 2
J. Ritchie, E. Burnett (1968)
A Precision Weighing Lysimeter for Row Crop Water Use Studies1Agronomy Journal, 60
C. Bavel, G. Stirk, K. Brust (1968)
Hydraulic Properties of a Clay Loam Soil and the Field Measurement of Water Uptake by Roots: I. Interpretation of Water Content and Pressure Profiles 1Soil Science Society of America Journal, 32
Maharaj Singh, D. Peters, J. Pendleton (1968)
Net and Spectral Radiation in Soybean Canopies1Agronomy Journal, 60
M. Jensen, D. Robb, C. Franzoy (1970)
Scheduling Irrigations Using Climate-Crop-Soil DataJournal of the Irrigation and Drainage Division, 96
M. Larue, D. Nielsen, R. Hagan (1968)
Soil Water Flux below a Ryegrass Root Zone1Agronomy Journal, 60
J. Philip (1957)
EVAPORATION, AND MOISTURE AND HEAT FIELDS IN THE SOILJournal of Meteorology, 14
M. Jensen, H. Haise (1963)
Estimating evapotranspiration from solar radiationJournal of the Irrigation and Drainage Division, 89
Black (1969)
655Soil Sci. Soc. Amer. Proc., 33
A model is presented for calculating the daily evaporation rate from a crop surface. It applies to a row crop canopy situation in which the soil water supply to the plant roots is not limited and the crop has not come into an advanced stage of maturation or senescence. The crop evaporation rate is calculated by adding the soil surface and plant surface components (each of these requiring daily numbers for the leaf area index), the potential evaporation, the rainfall, and the net radiation above the canopy. The evaporation from the soil surface Es is calculated in two stages: (1) the constant rate stage in which Es is limited only by the supply of energy to the surface and (2) the falling rate stage in which water movement to the evaporating sites near the surface is controlled by the hydraulic properties of the soil. The evaporation from the plant surfaces Ep is predicted by using an empirical relation based on local data, which shows how Ep is related to Eo through the leaf area index. The model was used to obtain the total evaporation rate E = Es + Ep of a developing grain sorghum (Sorghum bicolor L.) canopy in central Texas. The results agreed well with values for E measured directly with a weighing lysimeter.
Water Resources Research – Wiley
Published: Oct 1, 1972
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