EXCHANGEABLE NA, POLYMER, AND WATER-QUALITY EFFECTS ON WATER INFILTRATION AND SOIL LOSS

被引：10

作者：

BENHUR, M ^{[1
]}

CLARK, P ^{[1
]}

LETEY, J ^{[1
]}

机构：

[1] VOLCANI CTR,INST SOILS & WATER,IL-50250 BET DAGAN,ISRAEL

来源：

ARID SOIL RESEARCH AND REHABILITATION | 1992年 / 6卷 / 04期

关键词：

SOIL CONDITIONER; POLYACRYLAMIDE; POLYSACCHARIDE; SODICITY;

D O I：

10.1080/15324989209381325

中图分类号：

X [环境科学、安全科学];

学科分类号：

08 ; 0830 ;

摘要：

Increasing exchangeable sodium percentage (ESP) contributes to increased soil dispersion and swelling of clay, which reduces the infiltration rate and increases runoff Synthetic polymers are available that may decrease soil dispersion. A study was conducted to determine the effect of three polymers dissolved in water at 10 or 50 mg L-1 concentrations and applied through a rainfall simulator on the infiltration rate, erosion, and soil migration through the layer of a soil at ESP equal to 8.5 and 30.6 The polymers were a cationic polysaccharide and two anionic Polyacrylamides with different negative charge densities. The infiltration rate decreased with time and approached a final steady-state infiltration rate (FIR). The runoff water and associated sediment were captured and measured. Water coming through the soil layer and the amount of particulates contained in the water were measured. The FIR was significantly lower for the soil at ESP equal to 30.6 than at ESP equal to 8.5. There was no statistically significant effect of the polymer type or concentration on FIR. The amount of soil loss through erosion was significantly affected by the soil ESP, polymer type, and polymer concentration of the polymer application. More soil was in the runoff for the higher ESP than for the lower ESP The polymer treatment effects on soil loss were in the following order: cationic polysaccharide > untreated > low anionic PAM > higher-charged anionic PAM. Soil loss from application of the polymer at 50 mg L-1 was significantly less than at 10 mg L-1. The amount of soil migrating through the soil layer with the percolate was significantly higher for the higher ESP soil, whereas there was no significant effect of polymer treatment on this parameter

引用

页码：311 / 317

页数：7

共 18 条

[1]

Baver L.D., Gardner W.H., Gardner W.R., Soil Physics, (1972)

[2]

Ben-Hur M., Letey J., Effect of polysaccharides, clay dispersion and impact energy on water infiltration, Soil Science Society of America Journal, 53, pp. 223-238, (1989)

[3]

Ben-Hur M., Letey J., Shainberg I., Polymer effects on erosion under laboratory rainfall simulator conditions, Soil Science Society of America Journal, 54, pp. 1092-1095, (1990)

[4]

Ben-Hur M., Faris J., Malik M., Letey J., Polymers as soil conditioners under consecutive irrigations and rainfall, Soil Science Society of America Journal, 53, pp. 1173-1177, (1989)

[5]

Bradford J.M., Ferris J.E., Remley P.A., Interril soil erosion processes, I: Effect of surface sealing on infiltration, runoff, and soil splash detachment, Soil Science Society of America Journal, 51, pp. 1566-1571, (1987)

[6]

El-Morsy E.A., Malik M., Letey J., Interactions between water quality and polymer treatment on infiltration rate and clay migration, Soil Technology, 4, pp. 221-231, (1991)

[7]

Helalia A.M., Letey J., Cationic polymer effects on infiltration rates with a rainfall simulator, Soil Science Society of America Journal, 52, pp. 247-250, (1988)

[8]

Helalia A.M., Letey J., Graham R.C., Crust formation and clay migration effects on infiltration rates, Soil Science Society of America Journal, 52, pp. 251-255, (1988)

[9]

Kazman Z., Shainberg I., Gal M., Effect of low levels of exchangeable Na and phospho-gypsum on infiltration rate of various soils, Soil Science, 135, pp. 184-190, (1983)

[10]

Kleijn W.B., Oster J.D., Cook N., A rainfall simulator with nonrepetitious movement of drop outlets, Soil Science Society of America Journal, 43, pp. 1248-1251, (1979)

← 1 2 →