Clay dispersion and its relation to surface charge in a paddy soil of the Red River Delta, Vietnam

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Minh N. Nguyen
  • Stefan Dultz
  • Jörn Kasbohm
  • Duc Le

Research Organisations

External Research Organisations

  • University of Greifswald
  • Vietnam National University
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Details

Original languageEnglish
Pages (from-to)477-486
Number of pages10
JournalJournal of Plant Nutrition and Soil Science
Volume172
Issue number4
Publication statusPublished - Aug 2009

Abstract

Dispersion is an important issue for clay leaching in soils. In paddy soils of the Red River Delta (RRD), flooding with fresh water and relatively high leaching rates can accelerate dispersion and the translocation of clay. For the clay fraction of the puddled horizon of a typical paddy soil of the RRD, the effect of various cations and anions as well as humic acid (HA) at different pH values on the surface charge (SC) were quantified and the dispersion properties were determined in test tubes and described by the C 50 value. In the <2 μm fraction, dominated by illite, the proportion of 2:1 vs. 1:1 clay minerals is 5:1. The organic-C content of the clay fraction is 2.2%. Surface charge was found to be highly pH-dependent. At pH 8 values of -32 and at pH 1 of -8 mmol c kg -1 were obtained. Complete dispersion was observed at pH > 4, where SC is > -18 mmol c kg -1. The flocculation efficiency of Ca strongly depends on the pH. At pH 4, the C 50 value is 0.33, 0.66 at pH 5, and 0.90 mmol L -1 at pH 6. At pH 6, close to realistic conditions of paddy soils, the effect of divalent cations on the SC and flocculation decreases in the order: Pb > Cu > Cd > Fe II > Zn > Ca > Mn II > Mg; Fe II was found to have a slightly stronger effect on flocculation than Ca. An increase in concentrations of Ca, Mn II, and Mg from 0 to 1 mmol L -1 resulted in a change in SC from -25 to approx. -15 mmol c kg -1. In comparison, the divalent heavy-metal cations Pb, Cu, Cd, and Zn were found to neutralize the SC more effectively. At a Pb concentration of 1 mmol L -1, the SC is -2 mmol c kg -1. From pH 3 to 5, the dispersion of the clay fraction is facilitated rather by SO 2- 4 than by Cl-, which can be explained by the higher affinity of SO 2- 4 to the positively charged sites. With an increase of the amount of HA added, the SC continuously shifts to more negative values, and higher concentrations of cations are needed for flocculation. At pH 3, where flocculation is usually observed, the presence of HA at a concentration of 40 mg L -1 resulted in a dispersion of the clay fraction. While high anion concentrations and the presence of HA counteract flocculation by making the SC more negative, Fe IIL -1 and Ca (C 50 at pH 6 = 0.8 and 0.9 mmol L -1, respectively) are the main factors for the flocculation of the clay fraction. For Fe II and Ca, the most common cations in soil solution, the C 50 values were found to be relatively close together at pH 4, 5, and 6, respectively. Depending on the specific mineralogical composition of the clay fraction, SC is a suitable measure for the determination of dispersion properties and for the development of methods to keep clay particles in the soil in the flocculated state.

Keywords

    Aanion effects, Clay dispersion, Heavy metals, Humic acid, Paddy soil, Surface charge

ASJC Scopus subject areas

Cite this

Clay dispersion and its relation to surface charge in a paddy soil of the Red River Delta, Vietnam. / Nguyen, Minh N.; Dultz, Stefan; Kasbohm, Jörn et al.
In: Journal of Plant Nutrition and Soil Science, Vol. 172, No. 4, 08.2009, p. 477-486.

Research output: Contribution to journalArticleResearchpeer review

Nguyen MN, Dultz S, Kasbohm J, Le D. Clay dispersion and its relation to surface charge in a paddy soil of the Red River Delta, Vietnam. Journal of Plant Nutrition and Soil Science. 2009 Aug;172(4):477-486. doi: 10.1002/jpln.200700217
Nguyen, Minh N. ; Dultz, Stefan ; Kasbohm, Jörn et al. / Clay dispersion and its relation to surface charge in a paddy soil of the Red River Delta, Vietnam. In: Journal of Plant Nutrition and Soil Science. 2009 ; Vol. 172, No. 4. pp. 477-486.
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abstract = "Dispersion is an important issue for clay leaching in soils. In paddy soils of the Red River Delta (RRD), flooding with fresh water and relatively high leaching rates can accelerate dispersion and the translocation of clay. For the clay fraction of the puddled horizon of a typical paddy soil of the RRD, the effect of various cations and anions as well as humic acid (HA) at different pH values on the surface charge (SC) were quantified and the dispersion properties were determined in test tubes and described by the C 50 value. In the <2 μm fraction, dominated by illite, the proportion of 2:1 vs. 1:1 clay minerals is 5:1. The organic-C content of the clay fraction is 2.2%. Surface charge was found to be highly pH-dependent. At pH 8 values of -32 and at pH 1 of -8 mmol c kg -1 were obtained. Complete dispersion was observed at pH > 4, where SC is > -18 mmol c kg -1. The flocculation efficiency of Ca strongly depends on the pH. At pH 4, the C 50 value is 0.33, 0.66 at pH 5, and 0.90 mmol L -1 at pH 6. At pH 6, close to realistic conditions of paddy soils, the effect of divalent cations on the SC and flocculation decreases in the order: Pb > Cu > Cd > Fe II > Zn > Ca > Mn II > Mg; Fe II was found to have a slightly stronger effect on flocculation than Ca. An increase in concentrations of Ca, Mn II, and Mg from 0 to 1 mmol L -1 resulted in a change in SC from -25 to approx. -15 mmol c kg -1. In comparison, the divalent heavy-metal cations Pb, Cu, Cd, and Zn were found to neutralize the SC more effectively. At a Pb concentration of 1 mmol L -1, the SC is -2 mmol c kg -1. From pH 3 to 5, the dispersion of the clay fraction is facilitated rather by SO 2- 4 than by Cl-, which can be explained by the higher affinity of SO 2- 4 to the positively charged sites. With an increase of the amount of HA added, the SC continuously shifts to more negative values, and higher concentrations of cations are needed for flocculation. At pH 3, where flocculation is usually observed, the presence of HA at a concentration of 40 mg L -1 resulted in a dispersion of the clay fraction. While high anion concentrations and the presence of HA counteract flocculation by making the SC more negative, Fe IIL -1 and Ca (C 50 at pH 6 = 0.8 and 0.9 mmol L -1, respectively) are the main factors for the flocculation of the clay fraction. For Fe II and Ca, the most common cations in soil solution, the C 50 values were found to be relatively close together at pH 4, 5, and 6, respectively. Depending on the specific mineralogical composition of the clay fraction, SC is a suitable measure for the determination of dispersion properties and for the development of methods to keep clay particles in the soil in the flocculated state.",
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TY - JOUR

T1 - Clay dispersion and its relation to surface charge in a paddy soil of the Red River Delta, Vietnam

AU - Nguyen, Minh N.

AU - Dultz, Stefan

AU - Kasbohm, Jörn

AU - Le, Duc

N1 - Copyright: Copyright 2012 Elsevier B.V., All rights reserved.

PY - 2009/8

Y1 - 2009/8

N2 - Dispersion is an important issue for clay leaching in soils. In paddy soils of the Red River Delta (RRD), flooding with fresh water and relatively high leaching rates can accelerate dispersion and the translocation of clay. For the clay fraction of the puddled horizon of a typical paddy soil of the RRD, the effect of various cations and anions as well as humic acid (HA) at different pH values on the surface charge (SC) were quantified and the dispersion properties were determined in test tubes and described by the C 50 value. In the <2 μm fraction, dominated by illite, the proportion of 2:1 vs. 1:1 clay minerals is 5:1. The organic-C content of the clay fraction is 2.2%. Surface charge was found to be highly pH-dependent. At pH 8 values of -32 and at pH 1 of -8 mmol c kg -1 were obtained. Complete dispersion was observed at pH > 4, where SC is > -18 mmol c kg -1. The flocculation efficiency of Ca strongly depends on the pH. At pH 4, the C 50 value is 0.33, 0.66 at pH 5, and 0.90 mmol L -1 at pH 6. At pH 6, close to realistic conditions of paddy soils, the effect of divalent cations on the SC and flocculation decreases in the order: Pb > Cu > Cd > Fe II > Zn > Ca > Mn II > Mg; Fe II was found to have a slightly stronger effect on flocculation than Ca. An increase in concentrations of Ca, Mn II, and Mg from 0 to 1 mmol L -1 resulted in a change in SC from -25 to approx. -15 mmol c kg -1. In comparison, the divalent heavy-metal cations Pb, Cu, Cd, and Zn were found to neutralize the SC more effectively. At a Pb concentration of 1 mmol L -1, the SC is -2 mmol c kg -1. From pH 3 to 5, the dispersion of the clay fraction is facilitated rather by SO 2- 4 than by Cl-, which can be explained by the higher affinity of SO 2- 4 to the positively charged sites. With an increase of the amount of HA added, the SC continuously shifts to more negative values, and higher concentrations of cations are needed for flocculation. At pH 3, where flocculation is usually observed, the presence of HA at a concentration of 40 mg L -1 resulted in a dispersion of the clay fraction. While high anion concentrations and the presence of HA counteract flocculation by making the SC more negative, Fe IIL -1 and Ca (C 50 at pH 6 = 0.8 and 0.9 mmol L -1, respectively) are the main factors for the flocculation of the clay fraction. For Fe II and Ca, the most common cations in soil solution, the C 50 values were found to be relatively close together at pH 4, 5, and 6, respectively. Depending on the specific mineralogical composition of the clay fraction, SC is a suitable measure for the determination of dispersion properties and for the development of methods to keep clay particles in the soil in the flocculated state.

AB - Dispersion is an important issue for clay leaching in soils. In paddy soils of the Red River Delta (RRD), flooding with fresh water and relatively high leaching rates can accelerate dispersion and the translocation of clay. For the clay fraction of the puddled horizon of a typical paddy soil of the RRD, the effect of various cations and anions as well as humic acid (HA) at different pH values on the surface charge (SC) were quantified and the dispersion properties were determined in test tubes and described by the C 50 value. In the <2 μm fraction, dominated by illite, the proportion of 2:1 vs. 1:1 clay minerals is 5:1. The organic-C content of the clay fraction is 2.2%. Surface charge was found to be highly pH-dependent. At pH 8 values of -32 and at pH 1 of -8 mmol c kg -1 were obtained. Complete dispersion was observed at pH > 4, where SC is > -18 mmol c kg -1. The flocculation efficiency of Ca strongly depends on the pH. At pH 4, the C 50 value is 0.33, 0.66 at pH 5, and 0.90 mmol L -1 at pH 6. At pH 6, close to realistic conditions of paddy soils, the effect of divalent cations on the SC and flocculation decreases in the order: Pb > Cu > Cd > Fe II > Zn > Ca > Mn II > Mg; Fe II was found to have a slightly stronger effect on flocculation than Ca. An increase in concentrations of Ca, Mn II, and Mg from 0 to 1 mmol L -1 resulted in a change in SC from -25 to approx. -15 mmol c kg -1. In comparison, the divalent heavy-metal cations Pb, Cu, Cd, and Zn were found to neutralize the SC more effectively. At a Pb concentration of 1 mmol L -1, the SC is -2 mmol c kg -1. From pH 3 to 5, the dispersion of the clay fraction is facilitated rather by SO 2- 4 than by Cl-, which can be explained by the higher affinity of SO 2- 4 to the positively charged sites. With an increase of the amount of HA added, the SC continuously shifts to more negative values, and higher concentrations of cations are needed for flocculation. At pH 3, where flocculation is usually observed, the presence of HA at a concentration of 40 mg L -1 resulted in a dispersion of the clay fraction. While high anion concentrations and the presence of HA counteract flocculation by making the SC more negative, Fe IIL -1 and Ca (C 50 at pH 6 = 0.8 and 0.9 mmol L -1, respectively) are the main factors for the flocculation of the clay fraction. For Fe II and Ca, the most common cations in soil solution, the C 50 values were found to be relatively close together at pH 4, 5, and 6, respectively. Depending on the specific mineralogical composition of the clay fraction, SC is a suitable measure for the determination of dispersion properties and for the development of methods to keep clay particles in the soil in the flocculated state.

KW - Aanion effects

KW - Clay dispersion

KW - Heavy metals

KW - Humic acid

KW - Paddy soil

KW - Surface charge

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