Impact of monovalent cations on soil structure. Part I. Results of an Iranian soil

Farahani, Elham; Emami, Hojat; Keller, Thomas; Fotovat, Amir; Khorassani, Reza

doi:10.1515/intag-2016-0091

Cited by 29 publications

(17 citation statements)

References 37 publications

(56 reference statements)

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“…The results with regard to the impact of K on soil structure presented in this paper are apparently in contradiction to the findings presented in Part I of this series of papers (Farahani et al, 2018). Here, we demonstrate that clay dispersion was little affected by K and tended to decrease with increasing K concentration (Fig.…”

Section: Resultscontrasting

confidence: 99%

“…1), while we found that K strongly increased clay dispersion in Part I of our work ( Fig. 1 in Farahani et al, 2018). The si l soil used in this paper had a similar texture as the soil used in Part I, and the experimental procedure (the addition of monovalent cations in treatment solutions and incubation for one month) and treatment concentrations (K in the range of 0-60 mmolc l -1 ) were similar in both studies.…”

Section: Resultssupporting

confidence: 62%

“…In our study, we applied K in the range of 0-60 mmolc l -1 , and the results indicated that in the Iranian soil containing muscovite, K ions were not fixed and had a negative effect on soil structure (Part I of this series of papers; Farahani et al 2018), whereas in the Swiss soils containing illite, K ions were fixed, which prevented the negative effects of K on soil structure (this paper). We hypothesise that higher K concentrations have negative effects on soil structure in soils containing illite when the amount of K exceeds the 'K fixing potential' of illite.…”

Section: Resultsmentioning

confidence: 70%

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Impact of monovalent cations on soil structure. Part II. Results of two Swiss soils

Farahani¹,

Emami²,

Keller³

2018

International Agrophysics

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A b s t r a c t. In this study, we investigated the impact of adding solutions with different potassium and sodium concentrations on dispersible clay, water retention characteristics, air permeability, and soil shrinkage behaviour using two agricultural soils from Switzerland with different clay content but similar organic carbon to clay ratio. Three different solutions (including only Na, only K, and the combination of both) were added to soil samples at three different cation ratio of soil structural stability levels, and the soil samples were incubated for one month. Our findings showed that the amount of readily dispersible clay increased with increasing Na concentrations and with increasing cation ratio of soil structural stability. The treatment with the maximum Na concentration resulted in the highest water retention and in the lowest shrinkage capacity. This was was associated with high amounts of readily dispersible clay. Air permeability generally increased during incubation due to moderate wetting and drying cycles, but the increase was negatively correlated with readily dispersible clay. Readily dispersible clay decreased with increasing K, while readily dispersible clay increased with increasing K in Iranian soil (Part I of our study). This can be attributed to the different clay mineralogy of the studied soils (muscovite in Part I and illite in Part II).

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Section: Resultscontrasting

confidence: 99%

Section: Resultssupporting

confidence: 62%

Section: Resultsmentioning

confidence: 70%

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Impact of monovalent cations on soil structure. Part II. Results of two Swiss soils

Farahani¹,

Emami²,

Keller³

2018

International Agrophysics

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“…There was no correlation between net dispersive charge and Na concentration (sum of water‐soluble and exchangeable Na). Furthermore, the percentage of dispersible clay increased significantly with increasing K concentration ( r = 0.92, P = 0.004 and r = 0.77, P = 0.04 for EC 3 and 6 dS m −1 , respectively) and K:Na ratios ( r = 0.74, P = 0.05 and r = 0.78, P = 0.03 for EC 3 and 6 dS m −1 , respectively), but no relation was obtained between clay dispersion and Na concentration (Farahani et al ., ). Similar results, for a negative effect of K on soil structure, especially clay dispersion, have been reported in soils with different textures (sandy loam, loamy sand, loam, clay loam and clay) and clay mineralogy (mixture of kaolinite and illite, illite, kaolinite and smectite) in the literature (Czyz et al ., ; Rengasamy & Marchuk, ; Marchuk & Rengasamy, ; Emami et al ., ).…”

Section: Resultsmentioning

confidence: 99%

Effect of different K:Na ratios in soil on dispersive charge, cation exchange and zeta potential

Farahani

Emami

Fotovat

et al. 2018

European J Soil Science

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Summary The role of potassium (K) in clay dispersion in agricultural soils containing large concentrations of K could be similar to Na. This research was carried out to assess the effect of potassium to sodium ratios (K:Na) on net dispersive charge, Gapon selectivity coefficient (KG), zeta potential (ζ) and percentage of dispersible clay. Different K:Na ratios at two electrical conductivity levels (EC = 3 and 6 dS m−1) were added to an agricultural loamy soil. The results demonstrated that the net dispersive charge and percentage of dispersible clay showed positive relations with K concentration and K:Na ratio; also, the percentage of dispersible clay and net dispersive charge had a positive correlation, at both EC levels. Therefore, net dispersive charge as well as percentage of dispersible clay can show the degrading effect of K on soil structure. The KG values for K (KG(K)) were larger than those of Na (KG(Na)) because of large cation selectivity for K in soil. Neither KG(K) nor KG(Na) had a significant effect on the percentage of dispersible clay, but they did influence net dispersive charge, indicating that the status of cation exchange might affect dispersive charge of the soil. At both EC levels, absolute amounts of ζ, as an index of diffuse double layer (DDL) thickness, increased with increasing concentrations of monovalent cations (especially K). In addition, a strong positive correlation was observed between the dispersive charge and ζ. Our results demonstrated that K could affect soil structure because of a change in cation selectivity, with K increasing repulsive forces among clay particles and creating dispersion. Highlights K created repulsive forces between clay particles that led to clay dispersion. Net dispersive charge and dispersible clay increased with increasing K concentration and K:Na ratio. Cation exchange status (KG values) affected soil net dispersive charge significantly. A positive correlation between dispersive charge and zeta potential was observed.

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“…Cropping system management plays an important role in the construction and modification of the geomorphology and soil structure of sloping agricultural landscapes (De Alba et al, 2004;Arnáez et al, 2015). Inadequate conservation practices can promote a continuous degradation of soil structure (Nunes et al, 2017), resulting in the dispersion of particles as a result of the presence of unstable aggregates, impeding the retention of rainwater and favouring the displacement of these particles, thereby facilitating erosion (Beutler et al, 2001;Farahani et al, 2018a).…”

Section: Introductionmentioning

confidence: 99%

Methodological aspects of the quantification of dispersible clay and their relations with soil properties along a catena under no-till system

Paula¹,

Giarola²,

Lima³

et al. 2020

Int. Agrophys.

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A b s t r a c t. Continuous no-till management of sloping cultivated areas can promote soil property transformations, causing changes in aggregation and dispersion. The objective of this work was (i) to quantify the readily and mechanically dispersible clays using different methods and (ii) to examine their relationships with soil properties along a catena under no-till management. For this study, the catena was divided into three distinct parts: crest, upper-slope and mid-slope positions. Undisturbed soil cores were sampled at each slope position to determine the following soil properties: organic carbon, Ca 2+ , Mg 2+ , K + , Al 3+ , P, pH, cation exchange capacity and total clay content. Additionally, the levels of readily dispersible clay were measured using turbidimeter and hydrometer methods, whereas mechanically dispersible clay was quantified using the turbidimeter method. We observed high influence of total clay content and organic carbon on soil flocculation; P, Mg 2+ and cation exchange capacity were positively related to clay dispersion. Soil management and water transport downslope are probably influencing changes in soil properties and determining the distribution of dispersible clay contents along the catena. No relationships were observed between readily dispersible clay measured using turbidimeter and hydrometer in terms of quantity. Hydrometer and turbidimeter measurements can deliver significantly different results regarding dispersible clay quantification, potentially leading to misinterpretations concerning the amount of clay dispersed in water.

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Impact of monovalent cations on soil structure. Part I. Results of an Iranian soil

Cited by 29 publications

References 37 publications

Impact of monovalent cations on soil structure. Part II. Results of two Swiss soils

Impact of monovalent cations on soil structure. Part II. Results of two Swiss soils

Effect of different K:Na ratios in soil on dispersive charge, cation exchange and zeta potential

Methodological aspects of the quantification of dispersible clay and their relations with soil properties along a catena under no-till system

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