THE EFFECT OF LEVEL OF APPLICATION ON THE RESIDUAL VALUE OF SUPERPHOSPHATE ON A SANDY SOIL IN SOUTH-WESTERN AUSTRALIA

被引：12

作者：

BOLLAND, MDA

BARROW, NJ

机构：

[1] Western Australian Department of Agriculture, Baron-Hay Court, South Perth, 6151, Western Australia

[2] Division of Animal Production, CSIRO, Wembley, 6014, Western Australia

来源：

FERTILIZER RESEARCH | 1991年 / 29卷 / 02期

关键词：

SUPERPHOSPHATE; RESIDUAL VALUE; SANDY SOIL; LEACHING OF PHOSPHORUS; LUPINS; BARLEY; WHEAT;

D O I：

10.1007/BF01048956

中图分类号：

S15 [土壤学];

学科分类号：

0903 ; 090301 ;

摘要：

In a field experiment on deep, yellow, sandy soil near Badgingarra, Western Australia, the residual value of superphosphate applied one and two years previously was measured relative to freshly-applied superphosphate using yields of narrow-leafed lupin (Lupinus angustifolius), barley and wheat. In addition, soil samples were collected for measurement of bicarbonate-extractable soil P. This was also used to estimate the residual value of the superphosphate. For lupins and wheat, and for bicarbonate-extractable soil P, the residual value decreased with increasing level of application. For barley grain, the residual value was not significantly affected by the level of application. The decrease in residual value of superphosphate with increasing level of application is attributed to increased leaching of applied phosphorus (P) down the profile of the sandy soils as the level of application increases. This may reduce subsequent plant yields due to the delay in seedling roots reaching the P in the soil during the crucial early stages of plant growth. For lupins, the relationship between yield and the level of superphosphate applied was markedly sigmoidal. The relationship for wheat and barley was exponential. Consequently, at suboptimal levels of P application, lupins required about two to three times more P than wheat or barley to produce the same yield. However, lupins required less P to achieve near-maximum yield.

引用

页码：163 / 172

页数：10

共 20 条

[1] Official Methods of Analysis, (1975)
[2] Barrow N.J., Mendoza R.E., Equations for describing sigmoid yield responses and their application to some phosphate responses by lupins and by subterranean clover, Fert Res, 22, pp. 181-8, (1990)
[3] Barrow N.J., Shaw T.C., Sodium bicarbonate as an extractant for soil phosphate. I. Separation of the factors affecting the amount of phosphate displaced from soil from those affecting secondary adsorption, Geoderma, 16, pp. 91-107, (1976)
[4] Bolan N.S., Robson A.D., Barrow N.J., Plant and soil factors including mycorrhizal infection causing sigmoidal response of plants to applied phosphorus, Plant and Soil, 73, pp. 187-201, (1983)
[5] Bolland M.D.A., Residual value of phosphorus from superphosphate for wheat grown on soils of contrasting texture near Esperance, Western Australia, Australian Journal of Experimental Agriculture, 26, pp. 209-15, (1986)
[6] Bolland M.D.A., Baker M.J., Lunt R.J., Effectiveness of superphosphate and crandallite — millisite rock phosphates on a deep, very sandy soil as assessed by plant growth and soil extractable phosphate, Australian Journal of Experimental Agriculture, 27, pp. 647-656, (1987)
[7] Bolland M.D.A., Gilkes R.J., Reactive rock phosphate fertilizers and soil testing for phosphorus: the effect of particle size of the rock phosphate, Fert Res, 21, pp. 75-93, (1989)
[8] Bolland M.D.A., Gilkes R.J., Allen D.G., D'Antuono M.F., Residual value of superphosphate and Queensland rock phosphate for serradella and clover on very sandy soils as assessed by plant growth and bicarbonate — soluble phosphorus, Australian Journal of Experimental Agriculture, 27, pp. 275-282, (1987)
[9] Colwell J.D., The estimation of phosphorus fertilizer requirements of wheat in southern New South Wales by soil analysis, Australian Journal of Experimental Agriculture, 3, pp. 190-7, (1963)
[10] Jarvis R.J., Bolland M.D.A., Placing superphosphate at different depths in the soil changes its effectiveness for wheat and lupin production, Fert Res, 22, pp. 97-107, (1990)

← 1 2 →