Evaluating status change of soil potassium from path model

The purpose of this study is to determine critical environmental parameters of soil K availability and to quantify those contributors by using a proposed path model. In this study, plot experiments were designed into different treatments, and soil samples were collected and further analyzed in labor...

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Bibliographic Details
Published in:PloS one 2013, Vol.8 (10), p.e76712-e76712
Main Authors: He, Wenming, Chen, Fang
Format: Article
Language:English
Subjects:
Adsorption
Agricultural practices
Agriculture - methods
Carbon - analysis
Carbonates
Carbonates - analysis
Ecology
Efficiency
Environmental parameters
Equilibrium
Experiments
Fertilization
Genotype & phenotype
Humic Substances - analysis
Hydrogen-Ion Concentration
Laboratories
Magnesium - analysis
Mathematical models
Models, Theoretical
Nitrogen - analysis
Nutrition
Organic matter
Organic soils
pH effects
Phosphorus
Poaceae - growth & development
Potassium
Potassium - analysis
Potassium - chemistry
Rhizosphere
Science
Sodium
Sodium - analysis
Soil - chemistry
Soil investigations
Soil organic matter
Soil properties
Soil sciences
Soil solution
Soil treatment
Soil water
Solubility
Studies
Sulfur - analysis
Water chemistry
Water shortages
Water treatment
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Summary:The purpose of this study is to determine critical environmental parameters of soil K availability and to quantify those contributors by using a proposed path model. In this study, plot experiments were designed into different treatments, and soil samples were collected and further analyzed in laboratory to investigate soil properties influence on soil potassium forms (water soluble K, exchangeable K, non-exchangeable K). Furthermore, path analysis based on proposed path model was carried out to evaluate the relationship between potassium forms and soil properties. Research findings were achieved as followings. Firstly, key direct factors were soil S, ratio of sodium-potassium (Na/K), the chemical index of alteration (CIA), Soil Organic Matter in soil solution (SOM), Na and total nitrogen in soil solution (TN), and key indirect factors were Carbonate (CO3), Mg, pH, Na, S, and SOM. Secondly, path model can effectively determine direction and quantities of potassium status changes between Exchangeable potassium (eK), Non-exchangeable potassium (neK) and water-soluble potassium (wsK) under influences of specific environmental parameters. In reversible equilibrium state of [Formula: see text], K balance state was inclined to be moved into β and χ directions in treatments of potassium shortage. However in reversible equilibrium of [Formula: see text], K balance state was inclined to be moved into θ and λ directions in treatments of water shortage. Results showed that the proposed path model was able to quantitatively disclose moving direction of K status and quantify its equilibrium threshold. It provided a theoretical and practical basis for scientific and effective fertilization in agricultural plants growth.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0076712