The effects of pH on nutrient availability depend on both soils and plants

The effects of pH on nutrient availability are not solely caused by to the effects on reaction with soils but are an interaction between these effects and the effects on rate of uptake by plants. Some effects are specific to particular ions, but an important aspect is that plant roots and soil parti...

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Bibliographic Details
Published inPlant and soil Vol. 487; no. 1-2; pp. 21 - 37
Main Authors Barrow, N. J., Hartemink, Alfred E.
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 01.06.2023
Springer
Springer Nature B.V
Subjects
Adsorption
Agriculture
Analysis
Atoms & subatomic particles
Availability
Biomedical and Life Sciences
Boric acid
Boron
Cations
Ecology
Electrolytes
Growth
Hydrogen-ion concentration
Ions
Life Sciences
Molybdate
Nutrient availability
Nutrients
Nutritional aspects
pH effects
Plant Physiology
Plant roots
Plant Sciences
Plants
Review Article
Roots
Soil Science & Conservation
Soil sciences
Soils
Sorption
United States
Boron
Acidity: phosphorus
Soil reaction
Bioavailability
Sulfur
Molybdenum
Cobalt
Zinc
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Summary:The effects of pH on nutrient availability are not solely caused by to the effects on reaction with soils but are an interaction between these effects and the effects on rate of uptake by plants. Some effects are specific to particular ions, but an important aspect is that plant roots and soil particles both have variable charge surfaces. This influences availability, but in opposite directions. Sulfate is an example of this interplay. Its sorption by soil decreases markedly with increasing pH and thus “soil availability” increases. However, plant uptake also decreases with increasing pH thus “plant availability” decreases. For phosphate, the plant effect is stronger than the soil effect and uptake decreases with increasing pH. In contrast, effects of increasing pH on molybdate adsorption are so large that they dominate the overall effect. Sorption of cations, such as zinc or copper, increases with increasing pH but uptake rate also increases. The net effect is a small decrease in availability with increasing pH. Boron is an exception; there are small effects of pH on sorption; and it is the uncharged boric acid molecules that are taken up by plant roots. Their uptake is not affected by charge and uptake is proportional to the concentration of uncharged boric acid molecules. We argue that emphasis on the effects of pH on reactions with soil has led to a distorted picture of the effects of pH on nutrient availability.
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-023-05960-5