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Citric Acid Effect on the Abundance, Size and Composition of Water-Dispersible Soil Colloids and Its Relationship to Soil Phosphorus Desorption: A Case Study

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Citric Acid Effect on the Abundance, Size and Composition of Water-Dispersible Soil Colloids and Its Relationship to Soil Phosphorus Desorption: A Case Study. / Menezes-Blackburn, D.; Bol, R.; Klumpp, E. et al.
In: Journal of Soil Science and Plant Nutrition , Vol. 21, 30.09.2021, p. 2436-2446.

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Menezes-Blackburn D, Bol R, Klumpp E, Missong A, Nischwitz V, Haygarth PM. Citric Acid Effect on the Abundance, Size and Composition of Water-Dispersible Soil Colloids and Its Relationship to Soil Phosphorus Desorption: A Case Study. Journal of Soil Science and Plant Nutrition . 2021 Sept 30;21:2436-2446. Epub 2021 Jun 18. doi: 10.1007/s42729-021-00534-9

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@article{a35eae20ac8345589064ccfa772193ad,
title = "Citric Acid Effect on the Abundance, Size and Composition of Water-Dispersible Soil Colloids and Its Relationship to Soil Phosphorus Desorption: A Case Study",
abstract = "Citric acid exudation by plant roots is often linked to the mobilisation of recalcitrant soil phosphorus (P) for plant nutrition. In this case study, we have explored the effect of citric acid on the abundance, size and composition of water-dispersible soil colloids (WDC) to understand the mineral source of desorbed P and the chemical nature of P-carrying mobilized colloids. After incubation with citric acid, WDC were isolated using a soil particle-size fractionation method consisting of sedimentation, centrifugation and syringe filtration. The size range and composition of WDC was assessed using field-flow fractionation (FFF), combined with inductively coupled plasma mass spectrometry (ICP-MS) and UV spectrometry, for in vitro P desorption assay samples under the influence of increasing doses of citric acid. Three sharp and well-defined FFF particle size fractions of WDC containing P (12–23, 23–36 and 36–300 nm), with elution times matching carbon (C) peaks and offset from Fe, Al and Si fractions. The concentration of soluble or WDC-associated P, C, Fe, Al and Si increased in response to increasing citric acid doses. Silica colloids were only detected using syringe filtration below 5 µm. The Si, Fe and Al-containing fine colloid fractions (<600 nm) were positively correlated with P (de)sorption parameters measured by diffusive gradient in thin films in previous work. The P desorbed by citric acid originated predominantly from the disaggregation of Fe and Al oxides and silicate clays. The citric acid effect on mobilizing organic P carrying WDC fractions may increase soil organic P cycling and availability to plants.  ",
keywords = "Citric acid, Field-flow fractionation, Phosphorus availability, Phosphorus desorption, Soil colloids",
author = "D. Menezes-Blackburn and R. Bol and E. Klumpp and A. Missong and V. Nischwitz and P.M. Haygarth",
year = "2021",
month = sep,
day = "30",
doi = "10.1007/s42729-021-00534-9",
language = "English",
volume = "21",
pages = "2436--2446",
journal = "Journal of Soil Science and Plant Nutrition ",
issn = "0718-9508",
publisher = "SOC CHILENA CIENCIA SUELO",

}

RIS

TY - JOUR

T1 - Citric Acid Effect on the Abundance, Size and Composition of Water-Dispersible Soil Colloids and Its Relationship to Soil Phosphorus Desorption

T2 - A Case Study

AU - Menezes-Blackburn, D.

AU - Bol, R.

AU - Klumpp, E.

AU - Missong, A.

AU - Nischwitz, V.

AU - Haygarth, P.M.

PY - 2021/9/30

Y1 - 2021/9/30

N2 - Citric acid exudation by plant roots is often linked to the mobilisation of recalcitrant soil phosphorus (P) for plant nutrition. In this case study, we have explored the effect of citric acid on the abundance, size and composition of water-dispersible soil colloids (WDC) to understand the mineral source of desorbed P and the chemical nature of P-carrying mobilized colloids. After incubation with citric acid, WDC were isolated using a soil particle-size fractionation method consisting of sedimentation, centrifugation and syringe filtration. The size range and composition of WDC was assessed using field-flow fractionation (FFF), combined with inductively coupled plasma mass spectrometry (ICP-MS) and UV spectrometry, for in vitro P desorption assay samples under the influence of increasing doses of citric acid. Three sharp and well-defined FFF particle size fractions of WDC containing P (12–23, 23–36 and 36–300 nm), with elution times matching carbon (C) peaks and offset from Fe, Al and Si fractions. The concentration of soluble or WDC-associated P, C, Fe, Al and Si increased in response to increasing citric acid doses. Silica colloids were only detected using syringe filtration below 5 µm. The Si, Fe and Al-containing fine colloid fractions (<600 nm) were positively correlated with P (de)sorption parameters measured by diffusive gradient in thin films in previous work. The P desorbed by citric acid originated predominantly from the disaggregation of Fe and Al oxides and silicate clays. The citric acid effect on mobilizing organic P carrying WDC fractions may increase soil organic P cycling and availability to plants.  

AB - Citric acid exudation by plant roots is often linked to the mobilisation of recalcitrant soil phosphorus (P) for plant nutrition. In this case study, we have explored the effect of citric acid on the abundance, size and composition of water-dispersible soil colloids (WDC) to understand the mineral source of desorbed P and the chemical nature of P-carrying mobilized colloids. After incubation with citric acid, WDC were isolated using a soil particle-size fractionation method consisting of sedimentation, centrifugation and syringe filtration. The size range and composition of WDC was assessed using field-flow fractionation (FFF), combined with inductively coupled plasma mass spectrometry (ICP-MS) and UV spectrometry, for in vitro P desorption assay samples under the influence of increasing doses of citric acid. Three sharp and well-defined FFF particle size fractions of WDC containing P (12–23, 23–36 and 36–300 nm), with elution times matching carbon (C) peaks and offset from Fe, Al and Si fractions. The concentration of soluble or WDC-associated P, C, Fe, Al and Si increased in response to increasing citric acid doses. Silica colloids were only detected using syringe filtration below 5 µm. The Si, Fe and Al-containing fine colloid fractions (<600 nm) were positively correlated with P (de)sorption parameters measured by diffusive gradient in thin films in previous work. The P desorbed by citric acid originated predominantly from the disaggregation of Fe and Al oxides and silicate clays. The citric acid effect on mobilizing organic P carrying WDC fractions may increase soil organic P cycling and availability to plants.  

KW - Citric acid

KW - Field-flow fractionation

KW - Phosphorus availability

KW - Phosphorus desorption

KW - Soil colloids

U2 - 10.1007/s42729-021-00534-9

DO - 10.1007/s42729-021-00534-9

M3 - Journal article

VL - 21

SP - 2436

EP - 2446

JO - Journal of Soil Science and Plant Nutrition

JF - Journal of Soil Science and Plant Nutrition

SN - 0718-9508

ER -