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بررسی مقایسه ای اثر آلودگی نفت خام بر روی جمعیت میکروبی خاک جنگل و خاک صنعتی

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشگاه آزاد اسلامی، واحد کرمان

2 دانشگاه شهید باهنر کرمان

چکیده

هیدروکربن های نفتی آلاینده های گسترده ای هستند که از طریق انتقال نفت خام، نگهداری، حوادث نشت نفتی و فرآیندهای تصفیه در پالایشگاه ها وارد خاک می گردند. آلودگی نفتی دارای اثرات اکولوژیکی بر روی خاک می باشد بطوری که ترکیب و تنوع جامعه میکروبی را بر هم زده و اثراتی نیز بر روی فعالیت ریزجانداران و آنزیم های خاک دارد. در این تحقیق جهت مطالعه اثر نفت خام بر روی جمعیت میکروبی خاک، دو نوع خاک متفاوت شامل خاک های صنعتی (مجاور تأسیسات نفتی و پتروشیمی شیراز) و جنگل تهیه و نمونه برداری شد و شش نوع میکروکازم طراحی گردید. هر خاک دارای سه میکروکازم با شرایط متفاوت شامل بدون آلودگی، آلوده به نفت و آلوده به نفت همراه با مواد غذایی نیتروژن و فسفر بود. شاخص هایی همچون جمعیت باکتری های هتروتروف، جمعیت باکتری های تجزیه کننده، آنزیم دهیدروژناز و میزان تجزیه نفت در مورد هر میکروکازم در یک دوره زمانی 120 روزه بطور جداگانه سنجش گردید. نتایج این تحقیق نشان داد که بالاترین میزان باکتری های هتروتروف مربوط به خاک جنگل با ارزش 108 × 8 می باشد. بطور کلی تعداد باکتری های تجزیه کننده در خاک ها بطور قابل توجهی کمتر از تعداد کل باکتری های هتروتروف در خاک ها بود. کمیت باکتری های تجزیه کننده تا روز 60 آزمایش بصورت کاهشی و پس از آن تا انتهای آزمایش افزایش داشت. در بین سه نوع مختلف میکروکازم، میکروکازم آلوده به نفت همراه با افزودن منابع نیتروژن و فسفر بالاترین فعالیت آنزیمی دهیدروژناز را دارد. از لحاظ تجزیه زیستی نفت خام در خاک، بیشترین میزان تجزیه مربوط به خاک در میکروکازم صنعتی (95 %) بود. تحلیل آماری داده ها نشان داد که یک ارتباط معنی دار بین تعداد کل باکتری های هتروتروف که با روش MPN سنجیده شده با سایر شاخص های مورد بررسی وجود دارد. با بکارگیری نتایج حاصله از این تحقیق می توان بر حسب نوع خاک راهکارهای مناسبی جهت احیای زیستی آن ها پیشنهاد نمود.

کلیدواژه‌ها

عنوان مقاله [English]

Comparative Study of Crude Oil Contamination Effect on Industrial and Forest Soil Microbial Community

نویسندگان [English]

  • Nasrin Ansari 1
  • Mehdi Hassanshahian 2
  • MohammadReza Khoshro 1

1 Kerman branch, Islamic Azad University

2 Shahid Bahonar University of Kerman

چکیده [English]

Introduction: Petroleum hydrocarbons are widespread pollutant that enters to soil by some pathwayssuch as: Transportation of crude oil, conservation of oil compounds, crude oil spill and treatment process on refineries. Oil pollution has some ecological effect on soil that disturbed composition and diversity of microbial community. Also this pollution has some effects on microbial activity and enzymes of soil. Forests ecosystems may be polluted with petroleum hydrocarbons via different ways such as transportation and spill of crude oil from resource of petroleum storage. Industrial soil defined as the soils that located in industrial area such as petrochemical plant, mine, chemical factories and etc. These soils always contaminated to many pollutant such as: oil, diesel and heavy metals. These pollutants have some effects on the texture of the soil and microbial community. The aim of this research is to understand the effect of oil pollution on two different soils.
Material and Methods: In order to evaluate the effect of crude oil on soil microbial community, two different soil samples were collected from industrial and forest soils. Six microcosms were designed in this experiment. Indeed each soil sample examined inthree microcosms asunpolluted microcosm, polluted microcosm, and polluted microcosm with nutrient supply of Nitrogen and PhosphorusSome factors were assayed in each microcosm during 120 days of experiment. The included study factors were: total heterotrophic bacteria, total crude oil degrading bacteria, dehydrogenase enzyme and crude oil biodegradation. For enumeration of heterotrophic bacteria nutrient agar medium was used. In this method serial dilutions were done from each soil and spread on nutrient agar medium then different colonies were counted. For enumeration of degrading bacteria Bushnel-Hass (BH) medium were used. The composition of this medium was (g/lit): 1 gr KH2PO4, 1gr K2HPO4, 0.2 gr MgSO4.7H2O, 0.02 gr CaCl2, 1 gr NH4NO3, and two drops of FeCl3 60% , the pH was 7. The carbon source of this medium was crude oil (1%). In MPN method microplates (24 well) were utilized and turbidity was calculated as positive index.
Results and Discussion: The results of this study showed that the highest quantity of heterotrophic bacteria was related to forest soil (8 × 108). The quantities of degradative bacteria significantly were lower than heterotrophic bacteria in all soil microcosms. This result may be expected because heterotrophic bacteria can use other carbon sources instead of crude oil such as organic carbon, suger and some nutrients that exist in the soil, but degrading bacteria have some limit in the use of organic carbons and only capable to use crude oil hydrocarbons. Sothe quantity of these bacteria is lower than heterotrophic bacteria. The quantity of degradative bacteria have decrement pattern until 60th day of experiment but after this day these bacteria have increment pattern. This result can be interpreted as from beginning of experiment until 60th day of experiment the bacteria adapted to toxic effect of crude oil and after this time the quantity of bacteria increased and have ability to use pollutant in the soil. The best deydrogenase activity between different microcosms related to polluted microcosm with nutrient. This result confirms that nitrogen and phosphorus can decrease the damage effect of crude oil on soil microbial community. The mechanism of this attenuation of toxicity effect of crude oil on microbial community can be related to enhance bioavailability of essential elements for bacteria in the soil. So after oil pollution of an area, soil supply upto nitrogen and phosphorus demand must be mentioned as a necessary practice to decrease the toxicity effect of pollutants. The highest biodegradation of crude oil in all studied soils belonged to industrial microcosm (95 %). It can be explained by adaptation theory because the bacteria in the industrial soil were better adapted to different pollutants and these bacteria have more capability for biodegradation of crude oil. By this reasonthe rate of degradation of crude oil in the industrial soil were higher than forest soil. Statistical analysis of the results showed that there was a significant correlation between MPN quantity of heterotrophic bacteria and other assayed factors. Also, forest soil seemed to have significant difference with other soils.
Conclusion: according to the obtained results by this study, it can be possibly proposed appropriate strategies for bioremediation of different studied soil types. The selection of best bioremediation strategies belong to specific types of soil. Just as this research confirmed that the type of soil plays significant role in the percentage of degradation.

کلیدواژه‌ها [English]

  • Biodegradation
  • Crude oil
  • Microcosm
  • Pollution
  • Soil
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آب و خاک
دوره 30، شماره 4 - شماره پیاپی 48
مهر و آبان 1395
صفحه 1219-1231
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  • تاریخ دریافت: 03 خرداد 1394
  • تاریخ پذیرش: 03 خرداد 1394
  • تاریخ اولین انتشار: 01 آبان 1395
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