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Phosphorus Fertilization with Drip Irrigation¹

ABSTRACT

Application of plant nutrients with drip irrigation systems is desirable for labor and energy savings and flexibility in timing nutrient applications. Evaluations of P movement in the soil and uptake by tomatoes (Lycopersicum esculentum) were made when orthophosphate and glycerophosphate were applied through a drip irrigation system and in comparison with 26 kg of P/ha banded below the seed at planting. A significantly higher P content was measured in seedling leaves when 26 kg of P/ha was applied by drip irrigation than when the same rate was banded. No differences in P content of whole tops of seedlings were measured at equal rates of inorganic or organic P applied through the drip system. There was a significant linear response of P uptake to P rate.

With drip irrigation, orthophosphate moved a much greater distance into the soil than had been previously observed for comparable application rates per hectare. Glycerophosphate moved 5 to 10 cm farther through the soil at application rates of 6.5 and 13 kg of P/ha than did orthophosphate. At the relatively high rate of 39 kg of P/ha, orthophosphate moved 25 cm horizontally and 30 cm vertically in the soil profile. Movement of orthophosphate resulted from saturation of the soil reaction sites near the point of application with phosphorus and subsequent mass flow with the soil water. The distance of P movement was proportional to the application rate. Glycerophosphate must undergo enzymatic hydrolysis before releasing orthophosphate ions into the soil solution where orthophosphate can be removed from solution by soil reactions. Consequently, glycerophosphate moved farther than orthophosphate at low application rates.

¹ Contribution from the Dep. of Land, Air, and Water Resources, Univ. of California, Davis.

² Extension Soils Specialist, Assistant Professor of Soils, Associate Water Scientist, Specialist, and Associate Professor of Soil Science, respectively, Dep. of Land, Air, & Water Resources, Univ. of California, Davis, CA 95616.

Received for publication May 21, 1975. Accepted for publication August 19, 1975.

This article has been cited by other articles:

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