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Fertilizer and soil P uptake by maize, as affected by soil P level, granule size, and solubility of phosphate sources

Published online by Cambridge University Press:  27 March 2009

G. L. Terman
Affiliation:
National Fertilizer Development Centre, Tennessee Valley Authority, Muscle Shoals, Alabama, U.S.A.
S. E. Allen
Affiliation:
National Fertilizer Development Centre, Tennessee Valley Authority, Muscle Shoals, Alabama, U.S.A.

Summary

Two greenhouse pot experiments were conducted to evaluate labelled concentrated superphosphate (CSP) and labelled dicalcium phosphate (DCP) alone and in mixtures for maize grown on soils low, high and very high in available P. On the low P soil yield of dry forage, total uptake of P and uptake of fertilizer P increased linearly with 0, 20, 40 and 80 ppm of P applied as the various fine and granular sources varying widely in P water solubility. Hence, all of these criteria were highly correlated and suitable for evaluating effectiveness of the P on the low P soil. On the soil high and very high in P, only uptake of fertilizer P, which also increased linearly with rate of application, was suitable for evaluating the sources. Total uptake of fertilizer P decreased with increase in soil P level, but relative differences among granular sources were similar at the three soil P levels. Effectiveness of the P fertilizers decreased markedly with decreasing water solubility of the granular sources on all soils; the same trend was true for the fine sources at high soil P levels.

Actual uptake of fertilizer P or percentage recovery of labelled P applied was a better basis for source evaluation at high soil P levels than were calculated A values. There was little advantage in this study of labelling with 32P for P source evaluation at the low soil P level over use of multiple rates of the unlabelled fertilizers. However, labelling was essential at the higher soil P levels.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1969

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References

REFERENCES

Bouldin, D. R., DeMent, J. D. & Sample, E. C. (1960). Interaction between dicalcium and monoammonium phosphates granulated together. J. agric. Fd Chem. 8, 470–4.CrossRefGoogle Scholar
Devine, J. R., Gunary, D. & Larsen, S. (1968). Availability of phosphate as affected by duration of fertilizer contact with soil. J. agric. Sci., Camb. 71, 359–64.CrossRefGoogle Scholar
Engelstad, O. P. (1968). Use of multiple regression in fertilizer evaluation. Agron. J. 60, 327–9.CrossRefGoogle Scholar
Engelstad, O. P. & Khasawneh, F. E. (1969). Use of a concurrent Mitscherlich model in fertilizer evaluation. Agron. J. 61, 473–4.CrossRefGoogle Scholar
Fried, M. & Broeshart, H. (1967). The Soil Plant System. London and New York: Academic Press.Google Scholar
Fried, M. & Dean, L. A. (1952). A concept concerning the measurement of available soil nutrients. Soil Sci. 73, 263–71.CrossRefGoogle Scholar
Hall, N. S., Nelson, W. L., Krantz, B. A., Welch, C. D. & Dean, L. A. (1949). Utilization of phosphorus from various fertilizer materials. II. Cotton and com in North Carolina. Soil Sci. 68, 151–6.CrossRefGoogle Scholar
Larsen, S. (1952). The use of 32P in studies on the uptake of phosphorus by plants. Pl. Soil 4, 110.CrossRefGoogle Scholar
Mattingly, G. E. G. (1963). The agricultural value of some water and citrate soluble fertilizers: An account of recent work at Rothamsted and elsewhere. Proc.Fertil. Soc. No. 75, 5597.Google Scholar
Olsen, S. R. & Gardner, R. (1949). Utilization of phosphorus from various fertilizer materials. IV. Sugar beets, wheat and barley in Colorado. Soil Sci. 68, 163–9.CrossRefGoogle Scholar
Terman, G. L., Bouldin, D. R. & Webb, J. R. (1962). Evaluation of fertilizers by biological methods. Adv. Agron. 14, 265319.CrossRefGoogle Scholar
Terman, G. L., Hoffman, W. M. & Wright, B. D. (1964). Crop response to fertilizers in relation to content of ‘available’ phosphorus. Adv. Agron. 16, 59100.CrossRefGoogle Scholar
Terman, G. L. & Khasawneh, F. E. (1968). Crop uptake of fertilizer and soil phosphorus in relation to calculated A values. Soil Sci. 105, 346–54.CrossRefGoogle Scholar
Van Burg, P. F. J. (1963). The agricultural evaluation of nitrophosphates with particular reference to direct and cumulative phosphate effects, and to interaction between water-solubility and granule size. Proc. Fertil. Soc. No. 75, 554.Google Scholar
Wieczorek, G. A. & Breen, A. V. (1964). Radioactive phosphate fertilizer production at Boltsville, Maryland, 1947–62. Res. Rep. no. 371. U.S. Fertil. Lab. U.S.D.A., Beltsville, Maryland.Google Scholar