Research Article
BibTex RIS Cite
Year 2020, Volume: 26 Issue: 4, 380 - 387, 04.12.2020
https://doi.org/10.15832/ankutbd.412628

Abstract

References

  • Akça M O, Usta S & Keçeci M (2014). Kireçli ana materyal üzerinde oluşmuş bir toprakta iyot adsorpsiyonu ve desorpsiyonu. Toprak Bilimi ve Bitki Besleme Dergisi 2 (2): 57– 69.
  • Andersson M, Karumbunathan V & Zimmermann M B (2012). Global iodine status in 2011 and trends over the past decade. Journal of Nutrition 142(4): 744–750.
  • Choung S, Um W, Kim M & Kim M G (2013). Uptake mechanism for iodine species to black carbon. Environmental Science & Technology 47(18): 10349-10355.
  • Christiansen J V & Carlsen L (1991). Enzymatically controlled iodination reactions in the terrestrial environment. Radiochimica Acta 52(2): 327-334.
  • Dai J L, Zhu Y G, Zhang M & Huang Y Z (2004). Selecting iodine-enriched vegetables and the residual effect of iodate application to soil. Biological Trace Element Research 101(3): 265–276.
  • Dai J L, Zhang M, Hu Q H, Huang Y Z, Wang R Q & Zhu Y G (2009). Adsorption and desorption of iodine by various Chinese soils: II. Iodide and iodate. Geoderma 153(1-2): 130-135.
  • Francois R (1987). The influence of humic substances on the geochemistry of iodine in nearshore and hemipelagic marine sediments. Geochimica et Cosmochimica Acta 51(9): 2417-2427.
  • Garcia A C, De Souza LGA, Pereira M G, Castro R N, Garcia-Mina J M, Zonta E, Lisboa F J G & Berbera R L L (2016). Structure-property-function relationship in humic substances to explain the biological activity in plants. Scientific Reports 6: 20798.
  • Hansen V, Roos P, Aldahan A, Hou X & Possnert G (2011). Partition of iodine (129I and 127I) isotopes in soils and marine sediments. Journal of Environmental Radioactivity 102(12): 1096-1104.
  • Hartge K H (1971). Die Physikalische Untersuchung Von Böden. Enke Verlag Stuttgart.
  • Johnson C C (2003). The geochemistry of iodine and its application to environmental strategies for reducing the risks from iodine deficiency disorders (IDD). British Geological Survey, DFID kar project R7411, Report CR/03/057N.
  • Laurberg P, Cerqueira C, Ovesen L, Rasmussen L B, Perrild H, Andersen S, Pedersen I B & Carlé A (2010). Iodine intake as a determinant of thyroid disorders in populations. Best Practice & Research Clinical Endocrinology & Metabolism 24(1):13-27.
  • Lieser K H & Steinkopff T (1989). Chemistry of radioactive iodine in the hydrosphere and in the geosphere. Radiochimica Acta 46(1): 49–55.
  • Lobartini J C, Tan K H, Rema J A, Gingle A R, Pape C & Himmelsbach D S (1992). The geochemical nature and agricultural importance of commercial humic matter. Science of the Total Environment 113(1-2): 1–15.
  • Lyons G & Genc Y (2016). Commercial humates in agriculture: real substance or smoke and mirrors? Agronomy 6(4):50.
  • McNally S R (2011). The status of iodine and selenium in waikato soils (Thesis, Master of Science (MSc). University of Waikato, Hamilton, New Zealand.
  • Merzweiler A, Dahnert R, Felgentraeger H J & Richter D (1987). Occurrence of iodine in GDR soils used for agricultural production. Soils Fertility 50:1156.
  • Muramatsu Y, Uchida S, Sriyotha P & Sriyotha K (1990). Some considerations on the sorption and desorption phenomena of iodide and iodate on soil. Water, Air and Soil Pollution 49(1-2): 125-138.
  • Nath T, Priyankar, R & Amitava R (2010). Sorption and desorption behaviour of iodine in alluvial soils of Varanasi, India. Agricultura (Slovenia): 7(2), 9-14.
  • Pan B, Tao S, Dawson R W & Xing B S (2010). Formation of organo-mineral complexes as affected by particle size, pH, and dry–wet cycles. Australian Journal of Soil Research 48(8): 713-719.
  • Reiller P, Mercier-BIon F, Gimenez N, Barre N & Miserque F (2006). Iodination of humic acid samples from different origins. Radiochimica Acta 94(9-11): 739-745.
  • Smyth D & Johnson C C (2011). Distribution of iodine in soils of Northern Ireland. Geochemistry Exploration Environment Analysis 11(1): 25-39.
  • Sparks D L, Page A L, Helmke P A, Loeppert R H, Soltanpour P N, Tabatbai M A, Jhonston C T & Sumner M E (1996). Methods of soil analysis, Part 3 Chemical methods. Soil Science Society of America/ American Society of Agronomy, Madison, Wisconsin, USA.
  • Ticknor K V & Cho Y H (1990). Interaction of iodide and iodate with granitic fracture-filling minerals. Journal of Radioanalytical and Nuclear Chemistry 140(1): 75-90.
  • TS 5869 ISO 5073 Toplam (humik+fulvik) asit tayini “metodu. Türk Standartları Enstitüsü, ANKARA, 2003.
  • Uygur V & Karabatak I (2009). The effect of organic amendments on mineral phosphate fractions in calcareous soils. Journal of Plant Nutrition and Soil Science, 172(3): 336-345.
  • Whitehead D C (1973). The sorption of iodide by soils as influenced by equilibrium conditions and soil properties. Journal of the Science of Food and Agriculture 24(5): 547– 556.
  • Whitehead D C (1974). The influence of organic matter, chalk and sesquioxides on the solubility of iodide, elemental iodine and iodate incubated with soil. European Journal of Soil Science 25(4): 461-470.
  • Whitehead D C (1978). Iodine in soil profiles in relation and aluminium oxides and organic matter. Europen Journal of Soil Science, 29(1): 88–94.
  • Xu C, Zhang S J, Ho Y F, Miller E J, Roberts K A, Li H P, Schwehr K A, Otosaka S, Kaplan D I, Brinkmeyer R, Yeager C M & Santschi P H (2011). Is soil natural organic matter a sink or source for mobile radioiodine (129I) at the Savannah River Site? Geochimica et Cosmochimica Acta 75(19): 5716-5735.

Effect of Soil Organic Matter and Humates on Adsorption and Desorption Chemistry of Iodide in an Aridisol

Year 2020, Volume: 26 Issue: 4, 380 - 387, 04.12.2020
https://doi.org/10.15832/ankutbd.412628

Abstract

The translocation of iodine (I) from soil to food chain is largely determined by its adsorption/desorption reaction in soils. In this study, the effects of commercial humates (HA) applied on an Aridisol and indigenous soil organic matter (SOM) on the adsorption and desorption of iodide were investigated. For this reason, 1% and 3% HA (w/w) were incorporated into the whole soil (WS) and organic matter free (OMF) soil samples. Then soil samples were equilibrated with 0, 2, 4, 6, 8 and 10 mg L-1 iodide solution prepared in 0.01 molar CaCl2 for 40 h. The sorption data were better described by Langmuir isotherm (R2= 0.938) than Freundlich isotherm (R2= 0.763). The Langmuir sorption maximum of WS was 19.8 mg kg-1. Freundlich isotherm parameters were n= 0.89 and Kf= 2.165. Sorption maximum of OMF soil significantly increased up to 35.5 mg kg-1. HA applications reduced iodide sorption maximum of both WS and organic OMF soil samples. Desorption rate of the WS ranged between 0-15.3% whereas it decreased 0-0.65% upon removal OM. HA treatments, in general, reduced the desorption rates. However, increasing HA application resulted in higher desorption ratio in both WS and OMF soils. Consequently, either SOM or HA has preeminent role in the adsorption-desorption chemistry in soils. 

References

  • Akça M O, Usta S & Keçeci M (2014). Kireçli ana materyal üzerinde oluşmuş bir toprakta iyot adsorpsiyonu ve desorpsiyonu. Toprak Bilimi ve Bitki Besleme Dergisi 2 (2): 57– 69.
  • Andersson M, Karumbunathan V & Zimmermann M B (2012). Global iodine status in 2011 and trends over the past decade. Journal of Nutrition 142(4): 744–750.
  • Choung S, Um W, Kim M & Kim M G (2013). Uptake mechanism for iodine species to black carbon. Environmental Science & Technology 47(18): 10349-10355.
  • Christiansen J V & Carlsen L (1991). Enzymatically controlled iodination reactions in the terrestrial environment. Radiochimica Acta 52(2): 327-334.
  • Dai J L, Zhu Y G, Zhang M & Huang Y Z (2004). Selecting iodine-enriched vegetables and the residual effect of iodate application to soil. Biological Trace Element Research 101(3): 265–276.
  • Dai J L, Zhang M, Hu Q H, Huang Y Z, Wang R Q & Zhu Y G (2009). Adsorption and desorption of iodine by various Chinese soils: II. Iodide and iodate. Geoderma 153(1-2): 130-135.
  • Francois R (1987). The influence of humic substances on the geochemistry of iodine in nearshore and hemipelagic marine sediments. Geochimica et Cosmochimica Acta 51(9): 2417-2427.
  • Garcia A C, De Souza LGA, Pereira M G, Castro R N, Garcia-Mina J M, Zonta E, Lisboa F J G & Berbera R L L (2016). Structure-property-function relationship in humic substances to explain the biological activity in plants. Scientific Reports 6: 20798.
  • Hansen V, Roos P, Aldahan A, Hou X & Possnert G (2011). Partition of iodine (129I and 127I) isotopes in soils and marine sediments. Journal of Environmental Radioactivity 102(12): 1096-1104.
  • Hartge K H (1971). Die Physikalische Untersuchung Von Böden. Enke Verlag Stuttgart.
  • Johnson C C (2003). The geochemistry of iodine and its application to environmental strategies for reducing the risks from iodine deficiency disorders (IDD). British Geological Survey, DFID kar project R7411, Report CR/03/057N.
  • Laurberg P, Cerqueira C, Ovesen L, Rasmussen L B, Perrild H, Andersen S, Pedersen I B & Carlé A (2010). Iodine intake as a determinant of thyroid disorders in populations. Best Practice & Research Clinical Endocrinology & Metabolism 24(1):13-27.
  • Lieser K H & Steinkopff T (1989). Chemistry of radioactive iodine in the hydrosphere and in the geosphere. Radiochimica Acta 46(1): 49–55.
  • Lobartini J C, Tan K H, Rema J A, Gingle A R, Pape C & Himmelsbach D S (1992). The geochemical nature and agricultural importance of commercial humic matter. Science of the Total Environment 113(1-2): 1–15.
  • Lyons G & Genc Y (2016). Commercial humates in agriculture: real substance or smoke and mirrors? Agronomy 6(4):50.
  • McNally S R (2011). The status of iodine and selenium in waikato soils (Thesis, Master of Science (MSc). University of Waikato, Hamilton, New Zealand.
  • Merzweiler A, Dahnert R, Felgentraeger H J & Richter D (1987). Occurrence of iodine in GDR soils used for agricultural production. Soils Fertility 50:1156.
  • Muramatsu Y, Uchida S, Sriyotha P & Sriyotha K (1990). Some considerations on the sorption and desorption phenomena of iodide and iodate on soil. Water, Air and Soil Pollution 49(1-2): 125-138.
  • Nath T, Priyankar, R & Amitava R (2010). Sorption and desorption behaviour of iodine in alluvial soils of Varanasi, India. Agricultura (Slovenia): 7(2), 9-14.
  • Pan B, Tao S, Dawson R W & Xing B S (2010). Formation of organo-mineral complexes as affected by particle size, pH, and dry–wet cycles. Australian Journal of Soil Research 48(8): 713-719.
  • Reiller P, Mercier-BIon F, Gimenez N, Barre N & Miserque F (2006). Iodination of humic acid samples from different origins. Radiochimica Acta 94(9-11): 739-745.
  • Smyth D & Johnson C C (2011). Distribution of iodine in soils of Northern Ireland. Geochemistry Exploration Environment Analysis 11(1): 25-39.
  • Sparks D L, Page A L, Helmke P A, Loeppert R H, Soltanpour P N, Tabatbai M A, Jhonston C T & Sumner M E (1996). Methods of soil analysis, Part 3 Chemical methods. Soil Science Society of America/ American Society of Agronomy, Madison, Wisconsin, USA.
  • Ticknor K V & Cho Y H (1990). Interaction of iodide and iodate with granitic fracture-filling minerals. Journal of Radioanalytical and Nuclear Chemistry 140(1): 75-90.
  • TS 5869 ISO 5073 Toplam (humik+fulvik) asit tayini “metodu. Türk Standartları Enstitüsü, ANKARA, 2003.
  • Uygur V & Karabatak I (2009). The effect of organic amendments on mineral phosphate fractions in calcareous soils. Journal of Plant Nutrition and Soil Science, 172(3): 336-345.
  • Whitehead D C (1973). The sorption of iodide by soils as influenced by equilibrium conditions and soil properties. Journal of the Science of Food and Agriculture 24(5): 547– 556.
  • Whitehead D C (1974). The influence of organic matter, chalk and sesquioxides on the solubility of iodide, elemental iodine and iodate incubated with soil. European Journal of Soil Science 25(4): 461-470.
  • Whitehead D C (1978). Iodine in soil profiles in relation and aluminium oxides and organic matter. Europen Journal of Soil Science, 29(1): 88–94.
  • Xu C, Zhang S J, Ho Y F, Miller E J, Roberts K A, Li H P, Schwehr K A, Otosaka S, Kaplan D I, Brinkmeyer R, Yeager C M & Santschi P H (2011). Is soil natural organic matter a sink or source for mobile radioiodine (129I) at the Savannah River Site? Geochimica et Cosmochimica Acta 75(19): 5716-5735.
There are 30 citations in total.

Details

Primary Language English
Journal Section Makaleler
Authors

Muhittin Onur Akça This is me

Sadık Usta This is me

Mehmet Keçeci This is me

Veli Uygur

Publication Date December 4, 2020
Submission Date April 4, 2018
Acceptance Date October 30, 2018
Published in Issue Year 2020 Volume: 26 Issue: 4

Cite

APA Akça, M. O., Usta, S., Keçeci, M., Uygur, V. (2020). Effect of Soil Organic Matter and Humates on Adsorption and Desorption Chemistry of Iodide in an Aridisol. Journal of Agricultural Sciences, 26(4), 380-387. https://doi.org/10.15832/ankutbd.412628

Journal of Agricultural Sciences is published open access journal. All articles are published under the terms of the Creative Commons Attribution License (CC BY).