Arsenic fractionation and speciation in different textured soils supplied with farmyard manure and accumulation by sunflower under alkaline calcareous conditions.

Arsenic (As) is a naturally occurring element that is found in soil, water, and rocks. However, it can also be released into the environment through human activities. Arsenic is considered an environmental hazard because it is toxic to humans and animals and can cause serious health problems. Additionally, As-contaminated soil can limit plant growth and reduce crop yields, leading to economic losses for farmers. So, decreasing metal/metalloid solubility in soil by synthetic and organic amendments leads to better crop productivity on contaminated soils. The current study aimed to evaluate farmyard manure (FYM)-mediated changes in soil arsenic (As) behavior, and subsequent effects on achene yield of sunflower. Treatment plan comprised of two As levels, i.e., As-60 (60 mg kg-1) and As-120 (120 mg kg-1), four FYM levels (0, 20, 35, and 50 g kg-1), three textural types (sandy, loamy and clayey), and replicated thrice. Seven As fractions including water soluble-As (WS-As), labile-As (L-As), calcium-bound As (Ca-As), aluminum-bound As (Al-As), iron-bound As (Fe-As), organic-matter-bound As (OM-As), and residual-As (R-As) were determined which differed significantly (P ≤ 0.05) with FYM and soil texture. FYM supplementation decreased WS-As, L-As, Ca-As, and Al-As while increased Fe-As, OM-As, and R-As. The immobilizing effect of FYM increased with increasing its rate of application, and maximum effect was found in clayey soil. As speciation in soil also significantly (P ≤ 0.05) affected by FYM and soil texture, with a reduction in arsenate while increase in arsenite, mono-methyl arsenate, and di-methyl arsenate with increasing the rate of FYM supplementation. Bioaccumulation factor reduced with FYM addition, and highest reduction of 38.65 and 42.13% in sandy, 34.24 and 36.26% in loamy while 29.16 and 35.10% in clayey soils at As-60 and As-120, respectively, by 50 g kg-1 FYM compared with respective As treatments without FYM. As accumulation in plant parts was significantly (P ≤ 0.05) reduced by FYM with the subsequent improvement in achene yield.

Alteration in soil arsenic dynamics and toxicity to sunflower (Helianthus annuus L.) in response to phosphorus in different textured soils.

Being analogue to arsenic (As), phosphorus (P) may affect As dynamics in soil and toxicity to plants depending upon many soil and plant factors. Two sets of experiments were conducted to determine the effect of P on As fractionation in soils, its accumulation by plants and subsequent impact on growth, yield and physiological characteristics of sunflower (Helianthus annuus L.). Experimental plan comprised of two As levels (60 and 120 mg As kg-1 soil), four P (0-5-10-20 g phosphate rock kg-1 soil) and three textural types (sandy, loamy and clayey) with three replications. Among different As fractions determined, labile, calcium-bound, organic matter-bound and residual As increased while iron-bound and aluminum-bound As decreased with increasing P in all the three textural types. Labile-As percentage increased in the presence of P by 16.9-48.0% at As60 while 36.0-68.1% at As120 in sandy, 19.1-64.0% at As60 while 11.5-52.3% at As120 in loamy, and 21.8-58.2% at As60 while 22.3-70.0% at As120 in clayey soil compared to respective As treatment without P. Arsenic accumulation in plant tissues at both contamination levels declined with P addition as evidenced by lower bioconcentration factor. Phosphorus mitigated the As-induced oxidative stress expressed in term of reduced hydrogen peroxide, malondialdehyde while increased glutathione, and consequently improved the achene yield. Although, P increased As solubility in soil but restricted its translocation to plant, leading to reversal of oxidative damage, and improved sunflower growth and yield in all the three soil textural types, more profound effect at highest P level and in sandy texture.

Arsenic fractionation and its impact on physiological behavior of sunflower (Helianthus annuus L.) in three texturally different soils under alkaline calcareous conditions.

Soil textural composition may be important to control arsenic (As) behavior in soil and movement to plant. Two independent parallel experiments comprising of five As levels (0, 50, 100, 150, and 200 mg As kg-1 soil) and three soil textural types (sandy, loamy, and clayey) were designed for determining As fractionation in soils and its consequential effects on growth, yield, and physiological characteristics of sunflower (Helianthus annuus L.). Six As fractions, i.e., NH4Cl-extractable, NH4F-extractable, NaOH-extractable, H2SO4-extractable, H2O2-extractable, and HNO3-extractable, were determined. On an average, NH4Cl-extractable As (the most phytoavailable among the extracted fractions) was 48.9, 19.8, and 6.6% of the total As while the bioaccumulation factor for root ranged between 1.9 and 9.5, 1.8 and 4.4, and 0.8 and 2.1 for sandy, loamy, and clayey textured soils, respectively. There was an increase of 8.3, 5.6, and 6.0 times in malondialdehyde with a subsequent reduction in photosynthetic rate by 53.3, 42.7, and 38.0% and achene yield 90.0, 87.1, and 85.5% in sandy, loamy, and clayey textured soils, respectively at 200 mg As kg-1 as compared with the control. Antioxidant enzyme activities were increased with increasing As addition, and maximum activities were found at 150 mg As kg-1, where catalase activities were 377.7, 341.6, and 292.0%; peroxidase 788.5, 758.6, and 737.0%; and superoxide dismutase 235.7, 191.8, and 177.2% higher in sandy, loamy, and clayey textured soils, respectively as compared with the control. In conclusion, As fractionation was markedly influenced by soil texture, and toxic effects of As on growth, yield and physiological characteristics of sunflower were maximum in sandy followed by loamy and clayey textured soils in descending order.