• صفحه اصلی
  • بررسی میزان آلودگی فلز روی در منابع خاک و امکان‌سنجی حذف آن در شرایط گلخانه‌ای توسط گیاه نی‌تالابی و سلولز استخراجی آن (Pharagmites australis )

اشتراک گذاری

آدرس مقاله


کد مقاله : JEST-1707-3720 (R2) بازدید : 123 صفحه: 115 - 128

10.22034/jest.2019.28406.3720

نوع مقاله: پژوهشی

بررسی میزان آلودگی فلز روی در منابع خاک و امکان‌سنجی حذف آن در شرایط گلخانه‌ای توسط گیاه نی‌تالابی و سلولز استخراجی آن (Pharagmites australis )

محورهای موضوعی : آلودگی های محیط زیست (آب، خاک و هوا)

ملیحه امینی 1 , آتنا نعیمی 2 , هانا اعتمادی 3

1 - دانشیار گروه علوم و مهندسی محیط زیست، دانشکده منابع طبیعی، دانشگاه جیرفت.* (مسوول مکاتبات)
2 - دانشیار گروه شیمی، دانشکده علوم، دانشگاه جیرفت.
3 - استادیار گروه محیط زیست، پژوهشکده خلیج فارس، دانشگاه خلیج فارس، بوشهر.

تاریخ دریافت : 1396/04/13 تاریخ پذیرش : 1398/10/08 تاریخ انتشار : 1401/01/01

کلید واژه: آلودگی, سلولز, نی‌تالابی, فلز روی, کاشت گلخانه‌ای,

چکیده مقاله :

زمینه و هدف: فلزات سنگین از موارد تهدیدکننده سلامت اکوسیستم ها می باشند. تجمع فلزات در خاک امکان ورود آن ها به گیاهان و در نتیجه ریسک سلامت محصولات کشاورزی را افزایش می دهد. هدف از این تحقیق تعیین اثر تنش فلز روی بر گیاه Pharagmites australis در شرایط گلخانه ای بوده است.روش بررسی: آزمایش در قالب طرح کاملا تصادفی به صورت فاکتوریل با دو فاکتور و سه تکرار، سال 1395 در دانشگاه جیرفت انجام شد. هضم و آماده سازی نمونه ها به روش سوزاندن خشک صورت گرفت و جهت اندازه گیری غلظت عنصر روی از دستگاه جذب اتمی استفاده شد.یافته ها: نتایج آزمایش در شرایط گلخانه نشان داد با افزایش غلظت فلز روی در تیمارهای آزمایشی میزان جذب آن توسط بافت های زیرزمینی و اندام های هوایی گیاه افزایش می یابد هرچند تجمع چشم گیر روی در بافت های زیرزمینی بوده است و انتقال آن و تجمع در بافت های هوایی گیاه خیلی کمتر به دست آمده است.بحث و نتیجه گیری: با جذب و تجمع فلزات در اندام های زیرزمینی، توانایی رشد گیاه نیز با تغییر ویژگی های فیزیولوژیک کاهش یافته است. نتایج تجزیه رگرسیون نشان داد افزایش غلظت روی در بافت‌های گیاه نی تالابی تحت تاثیر سطوح تنش این فلز تابع یک منحنی درجه دوم با ضریب همبستگی بالای 90% بود که در سطح آماری 1 درصد معنی‌دار گردید. به طورکلی نتایج نشان داد که نی تالابی گیاهی نسبتا مقاوم در برابر تنش فلز ضروری و کمیاب روی، دارای فاکتور انتقال پایین و ظرفیت بالایی برای تجمع فلز روی در ریشه خود می‌باشد.

چکیده انگلیسی:

Background & Objective: Heavy metals cases are threatening the health of ecosystems. Accumulation of metals in the soil allows them to plant crops and thus increases the risk of agriculture crops health. The goal of this research was conducted to evaluate zinc stress resistance for Pharagmites australis in greenhouse conditions.Material and Methodology: Experimental design was performed in an entirely randomized plan having two factors and three replications, 2016 at University of Jiroft. Digestion and preparation of samples were done by dry burning method and then Zinc concentration was measured by atomic absorption.Findings: Greenhouse experiments results showed that with increasing in metal concentration treatments, its absorbing with shoot and root were increased. However, impressive accumulation of zinc was in root and its translocation and accumulation in shoot has been reported much less.Discussion & Conclusions: With absorb and accumulate of metals in root, ability of plant growth was decreased with changes in physiological characteristics. Results of regression analysis showed concentration increasing of zinc in P. australis organs under these metal stress condition were fitted as a quadratic function with R2 >90 (p<0.01). In summary results of this research show high relatively resistant of P. australis to zinc stress as necessary metal in plants, high accumulation capacity for metal in its root organ and low heavy metal translocation factor.

منابع و مأخذ:


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_||_

  1. Naderi, M. R., Daneshshahraki, A. R., Naderi, R., 2012. Some methods to increase the phytoremediation efficiency of heavy metals, Journal of Human and Environment. Vol. 22, pp. 26-38. (In Persian)
    2.
  2. Salehipour Baversad, M., Ghorbani, H., Afyuni, M., KheirAbadi, H., 2014. The Potential Risk Assessment of Heavy Metals on Human Health in Some Agricultural Products in Isfahan Province. Journal of Water and Soil Sciences, Vol. 18(67), pp71-81. (In Persian)
    3.
  3. Ebadati, Fateme., 2002, The role of aquatic plants in the refining of heavy metals in Miankaleh wetland, M.Sc. Thesis, Tarbiat Modares University. (In Persian)
    4.
  4. Ghafouri, M., Mortazavi, R., 1995, Hydrology, University of Tehran Press, Tehran, Iran. (In Persian)
    5.
  5. Rezvani, M., Ghorbanian, A. A., Nojavan, M., Sahba, M., 2013, Evaluation of Heavy Metal Contamination (Cadmium, Cobalt, Lead, Zinc and Manganese) in Eshtehard Aquifer, Journal of Environmental Science and Engineering, Vol. 1(1), pp. 14. (In Persian)
    6.
  6. Alipordarvari, H., Farmer Maywan, H., Sharifi, M., 2009, Evaluation of oral radish peroxidase activity and its relationship with soil heavy metal content. Journal of Science, University of Tehran. Vol. 1, pp. 37-43. (In Persian)
    7.
  7. Askari Mehrabadi, M., Nouri, M., Beigi, F., Amini, F., 2011, Evaluation of Acacia Phytoremediation in oil Contaminated Soils with Emphasis on Some Heavy Metals, Journal of Cell and Texture, Vol. 2(4), pp. 442-435. (In Persian)
    8.
  8. Guo, L., Cutright, T., 2014. Remediation of acid mine drainage (AMD)-contaminated soil by Phragmites australis and rhizosphere bacteria. Environment Science Pollution Resource.
    9.
  9. Aksoy, A., Duman, F., Sezen, G., 2005. Heavy metal accumulation and distribution in narrow-leaved cattail (Typha angustifolia) and common reed (Phragmites australis). Journal of Freshwater Ecology, Vol. 20(4), pp. 783-785.
    10.
  10. Kleche, M., Berrebbah, H., Grara, N., Bensoltane, S., Djekoun, M., Djebar, M., 2013. Phytoremediation using Phragmites australis roots of polluted water with metallic trace elements (MTE). Annals of Biological Research, Vol. 4 (3), pp. 130-133.
    11.
  11. Rahman Khan, M., Mahmud Khan, M., 2010. Effect of varying concentrations of nickel and cobalt on the plant growth and yield of chick pea. Aus Journal of Science. Vol. 4, pp. 1036-1046.
    12.
  12. Ebrahimi, M., 2012. Phytoremediation of Phragmites australis in contaminated soils with heavy metals, Range Journal, Vol. 6(1), pp. (In Persian)
    13.
  13. Taghizadeh, M., Kafi, M., Fattahi Moghaddam, M., Savaghebi, G., 2012. Effects of Lead Concentrations on Seed Germination of Turfgrass Genus and its Potential for Phytoremediation, Vol. 42(3), pp. 277-289. (In Persian)
    14.
  14. Alizadeh, M., Fathi, F., Torabian, A., 2008. Investigation of Heavy Metal Accumulation in Forage Plants Irrigated by Wastewater in South Tehran Case Study: Maize and Alfalfa. Journal of Environmental Science, Vol. 34, pp. 137-148. (In Persian)
    15.
  15. Doni, S., C, Macci., E, Peruzzi., M, Arenella., B, Ceccanti., G, Masciandaro., 2012. In situ phytoremediation of a soil historically contaminated by metals, hydrocarbons and polychlorobiphenyls, Journal of Environment Monitoring, Vol. 14, pp. 1383-1390.
    16.
  16. Zacchini, M., Pietrini, F., Mugnozza, G., Lori, V., 2008. Metal tolerance, accumulation and translocation in poplar and willow clones treated with cadmium in hydroponics. Water Air Soil Pollution. Vol. 197, pp. 23-34.
    17.
  17. Giuseppe, B., 2013. Comparative performance of trace element bioaccumulation and biomonitoring in the plant species Typha domingensis, Phragmites australis and Arundo donax, Ecotoxicology and Environmental Safety, Vol. 97, pp. 124–130.            
    18.
  18. Akbarpoursaraskanrood, F., Sadri, F., Gol Alizadeh, D., 2012. Phytoremediation of soils contaminated with some heavy metals by some native plants of Arasbaran protected area. Journal of Soil and Water Resources Protection, Vol. 4, pp. 53-65. (In Persian)
    19.
  19. Motasharzadeh, B., Sawaqbi Firoozabadi, G., Ali Khani, H. A., 2008. Identification of native plants and bacteria resistant to heavy metals in the lands around the lead mine and on the Shazand mansion in Arak for use in phytoremediation. Iranian Journal of Soil and Water Research, Vol. 39(1), pp. 163-174. (In Persian).
    20.
  20. Kancilic, G.B., Metin A.U. 2020. Phragmites australis as a new cellulose source: Extraction, characterization and adsorption of methylene blue. Journal of Molecular Liquid. Vol. 321, pp. 113313.
    21.
  21. Sánchez, M.D., Sánchez, R., Espinosa, E., Rosal, A., Rodríguez, A. 2017. Production of Cellulosic Pulp from Reed (Phragmitesaustralis) to Produce Paper and Paperboard. Bioprocess Engineering. Vol. 1(3), pp. 65-68.
    22.
  22. Farahbakhsh, M., 2011. The effect of different sources and amounts of potassium on the treatment of plants in a soil contaminated with cadmium, Journal of Agriculture (Research and Construction), Vol. 90, pp. 57-64. (In Persian)
    23.
  23. Abdul Latiff, A., Ahmad Tarmizi, K., Shukri, A., Baharudin, R., Hung, Y., 2012. Phytoremediation of Metals in Industrial Sludge by Cyperus Kyllingia-Rasiga, Asystassia Intrusa and Scindapsus Pictus Var Argyaeus Plant Specie. International Journal of Integration Enginering. Vol. 4, pp. 1-8.
    24.
  24. Farrag, F., Hussein, F., Fawzy, M., 2012. Phytoremediation Potentiality of Cyperus articulatus L. Life Science. Vol. 9, pp. 4032-4040.
    25.
  25. Subhashini, V., Swamy, A., 2014. Screening Potential of Three Native Grass Species for Phytoremediation of Heavy Metals. Europian Addict Resources. Vol. 2, pp. 5887-5903.
    26.
  26. Subhashini,V., Swamy, A., 2013. Uptake of heavy metals from contaminated soils by cyperus rotundus l. International Journal. Vol. 3, pp. 338-341.
    27.

 

 

 

 

 

 

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