اثر برهمکنش آهن و سرب بر کاهش قابلیت دسترسی سرب توسط گیاه ذرت در یک خاک آلوده به سرب

تبرته فراهانی, نرگس; بقائی, امیر حسین

doi:10.22067/jsw.v31i4.59049

اثر برهمکنش آهن و سرب بر کاهش قابلیت دسترسی سرب توسط گیاه ذرت در یک خاک آلوده به سرب

نوع مقاله : مقالات پژوهشی

نویسندگان

¹ واحد اراک، دانشگاه آزاد اسلامی، اراک، ایران

² دانشگاه آزاد اسلامی واحد اراک

10.22067/jsw.v31i4.59049

چکیده

هدف این تحقیق بررسی اثر کود گاوی غنی‌شده با لجن کنورتور بر مقدار جذب سرب توسط گیاه ذرت در یک خاک آلوده به سرب بود. تیمارهای آزمایشی شامل کاربرد مقادیر 0، 15 و 30 تن در هکتار کود گاوی غنی شده با لجن کنورتور (‌به میزان 0 و 5 درصد وزنی آهن خالص) و همچنین خاک تیمار شده با مقادیر 0، 200، 300 و400 میلی‌گرم سرب در کیلوگرم خاک از منبع نیترات سرب می‌باشد. سپس کود گاوی غنی شده به خاک آلوده به سرب اضافه و بذر ذرت (سینگل کراس 704) کاشته شد. بعد از گذشت 60 روز از شروع آزمایش، ویژگی‌های فیزیکی، شیمیایی خاک و غلظت سرب در خاک و گیاه ذرت اندازه‌گیری شد. کاربرد کود گاوی غنی شده با لجن کنورتور تاثیر معنی‌داری بر کاهش غلظت سرب ریشه و شاخساره گیاه داشت، به صورتی که کاربرد 30 تن در هکتار کود گاوی غنی شده در خاک آلوده به 300 میلیگرم سرب به ترتیب باعث کاهش 2 و 5/1 برابری در غلظت سرب ریشه و شاخساره گیاه شد. نتایج کلی این تحقیق حاکی از آن است که کاربرد کود گاوی غنی شده با 5 درصد آهن خالص از ترکیب لجن کنورتور احتمالاً توانسته است باعث کاهش قابلیت دسترسی سرب در خاک و گیاه شود که در این‌جا می‌توان به نقش بخش معدنی و آلی کود گاوی در کاهش قابلیت دسترسی به سرب اشاره کرد، هر چند که نقش اثر برهمکنش سرب و آهن در کاهش جذب سرب به وسیله گیاه نبایستی نادیده گرفته شود.

کلیدواژه‌ها

20.1001.1.20084757.1396.31.4.7.0

عنوان مقاله [English]

Interactive Effect of Fe and Pb on Decreasing Corn Pb Availability in a Pb-Polluted Soil

نویسندگان [English]

N. Tabarteh Farahani ¹
A.HA.H. Baghaie ²

¹ Islamic Azad Universty Arak Branch

² Department of Soil Science, Arak Branch, Islamic Azad University, Arak, Iran

چکیده [English]

Introduction: Lead (Pb) is of great concern in environment because of its toxicity to animals and humans. Lead is a cumulative toxin and known carcinogen. Although, plants do not require Pb for growth, the bioaccumulation index of Pb in plants exceeds that of most other trace elements. It is therefore important to control Pb concentration in plants, especially in the edible parts of crops to ensure food safety. There are many factors that control Pb accumulation and availability to plants in agricultural soils such as Pb source, Pb loading rate, soil pH, soil cation change capacity (CEC), chloride concentration in soil solution and soil organic matter content. These are important factors that should be considered for evaluating Pb phyto-availability. In addition, element interactions can also affect the elements uptake. Thus, this study was performed to investigate the effect of converter sludge-enriched cow manure on the changes in corn Pb uptake in a Pb-polluted soil under greenhouse condition.
Materials and Methods: This pot experiment was conducted under greenhouse condition around the city of Arak, using a Fine loamy, mixed and thermic, Typic Haplargids soil. A factorial experiment with a randomized complete block design with 24 treatments in three replications was carried out. The treatments consisted of applying enriched cow manure (0, 15 and 30 t ha-1) with 0% and 5% pure Fe from converter. To investigate the effect of converter sludge-enriched cow manure on the changes in corn Pb uptake, a non-saline soil with low carbon percentage was selected. The soil was polluted with Pb from Pb(NO3)2 source at the concentrations of 0, 200, 300 and 400 mg Pb kg-1 soil and incubated for one month. Cow manure was produced in a local farm and aged for two years before the experiment. The cow manure was enriched with converter sludge and incubated for three months in room temperature. Then, the enriched cow manure was added to the Pb polluted soil and corn (Zea mays L. single grass 704) seeds were sown. After 60 days from the experiment, soil physio-chemical properties and soil and plant Pb concentration were measured.
Results and Discussion: The greatest and least DTPA-extractable-Pb were determined in the polluted soil (400 mg Pb) without applying cow manure and the polluted soil (200 mg Pb) treated with 30 t ha-1 enriched cow manure, respectively. The DTPA-extractable-Pb in uncontaminated soils was not detectable by atomic absorption spectroscopy (AAS). Increasing the amount of cow manure caused a significant reduction in DTPA-extractable-Pb as applying 15 and 30 t ha-1 cow manure in a polluted soil (300 mg Pb) resulted in a significant decrease in DTPA-extractable-Pb by 11.9 and 23.4 units, respectively. This can be accounted for by the role of organic and inorganic fractions of cow manure in decreasing soil Pb availability. Interactions between Fe and Pb appear to influence the soil Pb availability as application of 15 and 30 t ha-1 converter sludge-enriched cow manure in 300 mg Pb-polluted soil caused a significant decline in soil Pb availability by 10.4 and 9.3 units, respectively. The highest and least root Pb concentration were observed in the polluted soil (400 mg Pb) without applying cow manure and the polluted soil (200 mg Pb) treated with 30 t ha-1 enriched cow manure, respectively. The corn root Pb concentration in unpolluted soils was not detectable by AAS. Applying 5% (W/W) pure Fe from converter sludge in the polluted soil (300 and 400 mg Pb) which were not manured significantly decreased the root Pb concentration by 19 and 9 units, respectively which is explainable by the interaction existing between Pb and Fe in soil. Furthermore, root Pb concentration was affected by converter sludge enriched-cow manure as applying 15 and 30 t ha-1 converter sludge cow manure in a polluted soil (400 mg Pb) significantly decreased the root Pb concentration by 20.8 and 10.9 units, respectively. However, the role of cow manure in increasing pH and decreasing root Pb concentration cannot be ignored. The greatest and least shoot Pb concentration was obtained for the polluted soil (400 mg Pb) without applying cow manure and the polluted soil (200 mg Pb) treated with 30 t ha-1 enriched cow manure, respectively. The corn shoot Pb concentration in unpolluted soils was not detectable by atomic absorption spectroscopy (AAS). Interaction effects were also observed for shoot Pb concentration as using 5% (W/W) pure Fe from converter sludge in the polluted soil (300 and 400 mg Pb) which were not treated by cow manure significantly decreased the shoot Pb concentration by 4.1 and 4.7 units, respectively.
Conclusion: The results of this study showed that interactions between Pb and Fe seem to play an important role in reducing root and shoot Pb concentration. On the other hand, applying cow manure can increase the soil sorption properties such as CEC and decrease the soil Pb availability and plant Pb uptake which is explainable by the fact that the organic and inorganic fractions of manure impact the Pb availability. However, the influences of soil physico-chemical properties such as pH upon soil Pb availability should be taken into account.

کلیدواژه‌ها [English]

Converter sludge
Cow manure
Enrichment
Heavy metal
Pollution

مراجع

1- Abbaspour A., Kalbasi M., and Shariatmadari H. 2004. Effect of steel converter sludge as iron fertilizer and soil amendment in some calcareous soils. Journal of plant nutrition, 27: 377-394.

2- Abu Zinada I., Abou Auda M., Ali S., and El E. 2011. Impact of soil lead pollution and iron foliar application on Spinacea oleracea (L.). Advances in Agriculture and Botanics, 3: 116-126.

3- Agegnehu G., Nelson P.N., and Bird M.I. 2016. Crop yield, plant nutrient uptake and soil physicochemical properties under organic soil amendments and nitrogen fertilization on Nitisols. Soil and Tillage Research, 160: 1-13.

4- Alidadi Khaliliha M., Dordipour E., and Barani Motlagh M. 2016. Interactive effect of iron and lead on growth and their uptake in Cress (Lepidium sativum L.). Journal of Soil Management and Sustainable Production, 5: 41-59 (in Persian with English abstract).

5- Allen S.E., Grimshaw H.M., and Rowland A.P. 1986. Chemical analysis p. 285-344. In: P.D. Moore and S.B. Chapman (eds.). Methods in Plant Ecology, Blackwell Scientific Publication, Oxford, London.

6- Baghaie A., Khoshgoftarmanesh A.H., Afyuni M., and Schulin R. 2011. The role of organic and inorganic fractions of cow manure and biosolids on lead sorption. Soil Science and Plant Nutrition, 57: 11-18.

7- Baghaie A.H., Khoshgoftarmanesh A.H., and Afyuni M. 2010. Crop effects on lead fractionation in a soil treated with lead organic and inorganic sources. Journal of residuals science and technology, 7: 131-138.

8- Bremner J.M. 1996. Nitrogen-total. p. 1085-1121. In D. L. Sparks (ed.), Methods of Soil Analysis. Part 3 , 3rd Ed.,American Society of Agronomy, Madison. WI.

9- Fodor F. 2006. Heavy metals competing with iron under conditions involving phytoremediation. p 129-151. In: L.L. Barton and J. Abadia (eds.), Iron Nutrition in Plants and Rhizospheric Microorganisms, Springer, Dordrecht, The Netherlands.

10- Gee G.W., and Bauder J.W. 1986. Particle-size analysis. p. 383-409. In: A. Klute (ed.). Methods of Soil Analysis, Part 1. Physical and Mineralogical Methods, American society of agronomy, Madison, WI.

11- He Z.-l., and Yang X.-e. 2007. Role of soil rhizobacteria in phytoremediation of heavy metal contaminated soils. Journal of Zhejiang University Science B, 8: 192-207.

12- Islam E., Liu D., Li T., Yang X., Jin X., Mahmood Q., Tian S., and Li J. 2008. Effect of Pb toxicity on leaf growth, physiology and ultrastructure in the two ecotypes of Elsholtzia argyi. Journal of Hazardous Materials, 154: 914-926.

13- Islam E., Yang X., Li T., Liu D., Jin X., and Meng F. 2007. Effect of Pb toxicity on root morphology, physiology and ultrastructure in the two ecotypes of Elsholtzia argyi. Journal of Hazardous Materials, 147: 806-816.

14- Karami S., and Ronaghi A. 2016. Interaction Effects of Cadmium and Wheat or Alfalfa Residues on Corn Yield and Nutrients Uptake. Iranian Journal of Soil Research, 30: 13-23 (in Persian with English abstract).

15- Li J., Gan J., and Hu Y. 2016. Characteristics of Heavy Metal Species Transformation of Pb, Cu, Zn from Municipal Sewage Sludge by Thermal Drying. Procedia Environmental Sciences, 31: 961-969.

16- Lindsay W.L., and Norvell W.A. 1978. Development of a DTPA soil test for zinc, iron, manganese, and copper. Soil Science Society of America Journal, 42: 421-428.

17- Mansouri T., Golchin A., and Fereidooni J. 2016. The Effects of EDTA and H2SO4 on Phyto-extraction of Pb from contaminated Soils by Radish. Journal of Water and Soil, 30: 194-209 (in Persian with English abstract).

18- Matos G., and Arruda M. 2003. Vermicompost as natural adsorbent for removing metal ions from laboratory effluents. Process Biochemistry, 39: 81-88.

19- Melali A.R., and Shariatmadari H. 2008. Application of Steel Making Slag and Converter Sludge in Farm Manure Enrichment for Corn Nutrition in Greenhouse Conditions. Journal of Water and Soil Science, 11: 505-513 (in Persian with English abstract).

20- Menon M., Hermle S., Günthardt-Goerg M.S., and Schulin R. 2007. Effects of heavy metal soil pollution and acid rain on growth and water use efficiency of a young model forest ecosystem. Plant and Soil, 297: 171-183.

21- Mohammadi Torkashvand A. 2011. Effect of steel converter slag as iron fertilizer in some calcareous soils. Acta Agriculturae Scandinavica, Section B-Soil and Plant Science:, 61: 14-22.

22- Molaei S., Shirani H., Hamidpour M., Shekofteh H., and Besalatpour A.A. 2016. Effect of Vermicompost, Pistachio Kernel and Shrimp Shell on Some Growth Parameters and Availability of Cd, Pb and Zn in Corn in a Polluted Soil. Journal of Water and Soil Science, 19: 113-124 (in persian with English abstract(.

23- Motesharezadeh B., and SavaghebI G., R 2011. Study of sunflower plant response to cadmium and lead toxicity by usage of PGPR in a calcareous soil. Journal of Water and Soil, 25: 1069-1079 (in Persian with English abstract).

24- Nelson D.W., and Sommers L.E. 1996. Total carbon, organic carbon, and organic matter. p. 539–579. In A.L. Page et al. (ed.) Methods of Soil Analysis, Part 2. Chemical and Microbiological Properties, American Society of Agronomy, Madison, Wisconsin, USA.

25- Nelson R.E. 1982. Carbonate and gypsum. p. 181-197. In: A.L. Page, R.H. Miller and D.R. Keeney (eds.). Methods of Soil Analysis, Part 2. Chemical and Microbiological Properties, American Society of Agronomy, Madison, Wisconsin, USA.

26- Olsen S.R., and Sommers L.E. 1982. Phosphorus. p. 403-431. In: A.L. Page, R.H. Miller and D.R. Keeney (eds.). Methods of Soil Analysis, Part 2. Chemical and Microbiological Properties, American Society of Agronomy, Madison, Wisconsin, USA.

27- Rezvani M., Zaefarian F., and Gholizadeh A. 2012. Lead and nutrients uptake by aeluropus littoralis under different levels of lead in soil. Water and Soil Science, 22: 73-86 (in Persian with English abstract).

28- Rhoades J.D. 1982. Cation exchange capacity. p. 149-157. In: A.L. Page, R.H. Miller and D.R. Keeney (eds.). Methods of Soil Analysis, Part 2. Chemical and Microbiological Properties, American Society of Agronomy, Madison, Wisconsin, USA.

29- Saadat K., and Barani Motlagh M. 2013. Influence of Iranian natural zeolites, clinoptilolite on uptake of lead and cadmium in applied sewage sludge by Maize (Zea mays. L.). Journal of Water and Soil Conservation, 20: 123-143 (in Persian with English abstract).

30- Sharifi M., Afyuni M., and Khoshgoftarmanesh A.H. 2010. Effects of sewage sludge, animal manure, compost and cadmium chloride on cadmium accumulation in corn and alfalfa. Journal of residuals science and technology, 7: 219-225.

31- Sharifi M., Afyuni M., and Khoshgoftarmanesh A.H. 2011. Effects of Sewage Sludge, Compost and Cow Manure on Availability of Soil Fe and Zn and their Uptake by Corn, Alfalfa and Tagetes Flower. Journal of Water and Soil Science, 15: 141-154 ((in Persian with English abstract).

32- Sharma A., Johri B., Sharma A., and Glick B. 2003. Plant growth-promoting bacterium Pseudomonas sp. strain GRP 3 influences iron acquisition in mung bean (Vigna radiata L. Wilzeck). Soil Biology and Biochemistry, 35: 887-894.

33- Shirani H., Hajabbasi M.A., Afyuni M., and Hemmat A. 2010. Impact of Tillage Systems and Farmyard Manure on Soil Penetration Resistance under Corn Cropping. Journal of Water and Soil, 14: 141-155 (in Persian with English abstract).

34- Solgi E., Esmaili-Sari A., Riyahi-Bakhtiari A., and Hadipour M. 2012. Soil contamination of metals in the three industrial estates, Arak, Iran. Bulletin of environmental contamination and toxicology, 88: 634-638.

35- Tafvizi M., and Motesharezadeh B. 2014. Effects of Lead on Iron, Manganese, and Zinc Concentrations in Different Varieties of Maize (Zea mays). Communications in Soil Science and Plant Analysis, 45: 1853-1865.

36- Tafvizi M., Motesharezadeh B., and Savaghebi G.R. 2014. Investigating the effects of lead contamination and foliar application of iron on some physiological characteristics in two forage corn (Zea mays L.) hybrids in calcareous soil. Iranian Journal of Field Crop Science, 45: 213-226 (in Persian with English abstract).

37- Zhong S., Shi J., and Xu J. 2010. Influence of iron plaque on accumulation of lead by yellow flag (Iris pseudacorus L.) grown in artificial Pb-contaminated soil. Journal of Soils and Sediments, 10: 964-970.