مجله علوم، مهندسی و فناوری هسته‌ای

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بررسی تأثیر کاربرد بیوچار و کاه گندم بر بهره‌وری کود نیتروژن در زراعت جو با استفاده از فن‌آوری ایزوتوپی N15

نوع مقاله : مقاله پژوهشی

نویسندگان

1 گروه مهندسی آب، دانشکدگان ابوریحان، دانشگاه تهران، کدپستی: 3391653755، تهران- ایران

2 پژوهشکده‌ی کشاورزی هسته‌ای، پژوهشگاه علوم و فنون هسته‌ای، سازمان انرژی اتمی ایران، صندوق پستی: 1498-31465، کرج - ایران

3 گروه مهندسی آب، پردیس ابوریحان، دانشگاه تهران، کدپستی: 3391653755، تهران- ایران

چکیده

امروزه مشکلاتی چون تغییرات آب و هوایی کره زمین و پیامدهای آن از جمله وقوع سیلاب­‌ها، خشکسالی­‌ها، ذوب یخچال‌­ها و بالا رفتن سطح آب اقیانوس‌­ها به صورت یک چالش جهانی مطرح هستند و باید به سرعت در جهت مهار این مشکلات اقدام شود. در بسیاری از منابع به جنبه­‌های مثبت کاربرد مواد آلی مثل بیوچار به عنوان نگه‌­دارنده رطوبت خاک و عناصر غذایی گیاه، کاهنده آب‌­شویی نیترات و انتشار گازهای گلخانه‌­ای اشاره شده است. بیوچار، ترکیب غنی از کربنی است که در اثر پیرولیز مواد آلی طبیعی تولید می‌­شود. در تحقیق حاضر مقادیر صفر درصد بیوچار (1B)، 5/2 درصد بیوچار (2B)، 5 درصد بیوچار (3B) و 5/7 درصد بیوچار (4B)، هم­‌چنین 5/2 درصد کاه گندم (1W) و 5 درصد کاه (2W) به خاک با بافت لوم رسی (1S) و نیز خاک لوم شنی (2S) افزوده ­شدند. این آزمایش گلدانی بر پایه طرح کاملاً تصادفی در سه تکرار در گلخانه و به روش ردیابی ایزوتوپ N15 انجام شد. در اثر کاربرد بیوچار، زیست توده گیاه و در نتیجه، میزان بازیافت کود نیتروژن افزایش یافت. این افزایش به خصوص در تیمار 4B1S بسیار معنی­‌دار بود (01/0P < ) و تا 35 درصد رسید. کاه باعث شد بهره‌­وری کود نیتروژن در تیمارهای 2W1S و  2W2S به ترتیب 94 درصد و 87 درصد کاهش یابد.

کلیدواژه‌ها

عنوان مقاله [English]

A study on the effect of biochar and wheat straw application on nitrogen fertilizer utilization in barley using 15N isotope technology

نویسندگان [English]

  • H. Abbasalian 1 2
  • J. Soltani 3
  • S.E. Hashemi 3
  • A. Borzouei 2
  • M. Ahmadvand 3

1 Department of Water Engineering, College of Aburaihan, University of Tehran, Postal code: 3391653755, Tehran-Iran

2 Department of Water Engineering, College of Aburaihan, University of Tehran, Postal code: 3391653755, Tehran-Iran

3 Water Engineering Department, College of Aburaihan, University of Tehran, Postal code: 3391653755, Tehran-Iran

چکیده [English]

Today, problems such as global climate change and its consequences such as floods, droughts, melting glaciers, ocean water level rise are considered globally, and actions should be taken immediately to contain these problems. Many sources pointed to the positive aspects of using organic matter such as biochar to retain soil moisture and plant nutrients, reducing nitrate leaching and greenhouse gas emissions. Biochar is a carbon-rich compound produced by pyrolysis of natural organic matter. In the present study, 0% biochar (B1), 2.5% biochar (B2), 5% biochar (B3), and 7.5% biochar (B4), 2.5% wheat straw (W1), and 5% straw (W2) were added to soil with clay loam texture (S1) and sandy loam soil (S2). This pot experiment was implemented based on a completely randomized design in three replications in the greenhouse using 15N Isotope tracing method. Due to biochar application, Crop yield and nitrogen fertilizer use efficiency increased. This increase was particularly significant in S1B4 treatment (P < 0.01) and reached up to 35%. Straw reduced nitrogen fertilizer utilization in S1W2 and S2W2 treatments by 94% and 87%, respectively

کلیدواژه‌ها [English]

  • Biochar
  • Greenhouse gas
  • Nitrogen fertilizer utilization
  • Isotope tracing
مراجع
1. J. Lehmann, S. Joseph, Biochar for environmental management: science, technology and implementation. Routledge, S. (Eds.). (2015).
 
2. M. Paneque, et al, Effect of biochar amendment on morphology, productivity and water relations of sunflower plants under non-irrigation conditions, Catena, 147, 280-287 (2016).
 
3. S.S. Akhtar, et al, Biochar enhances yield and quality of tomato under reduced irrigation, Agricultural Water Management, 138, 37-44 (2014).
 
4. Y. Wang, et al, Soil water infiltration and distribution characteristics under different biochar addition amount, Transactions of the Chinese Society of Agricultural Engineering, 32(8), 113-119 (2016).
 
5. M. Ramlow, et al, Broadcast woody biochar provides limited benefits to deficit irrigation maize in Colorado. Agriculture, Ecosystems & Environment, 269, 71-81 (2019).
 
6. G.H. Agbna, et al, Effects of deficit irrigation and biochar addition on the growth, yield, and quality of tomato, Scientia Horticulturae, 222, 90-101 (2017).
 
7. H.P. Schmidt, Fourfold increase in pumpkin yield in response to low-dosage root zone application of urine-enhanced biochar to a fertile tropical soil, Agriculture, 5(3), 723-741 (2015).
 
8. C.I. Kammann, et al, Plant growth improvement mediated by nitrate capture in co-composted biochar, Scientific reports, 5(1), 1-13 (2015).
 
9. P.G. Slavich, et al, Contrasting effects of manure and green waste biochars on the properties of an acidic ferralsol and productivity of a subtropical pasture, Plant and Soil, 366(1), 213-227 (2013).
 
10. E.R. Graber, et al, Biochar impact on development and productivity of pepper and tomato grown in fertigated soilless media, Plant and Soil, 337(1), 481-496 (2010).
 
11. L. Genesio, et al, Biochar increases vineyard productivity without affecting grape quality: Results from a four years field experiment in Tuscany, Agriculture, Ecosystems & Environment, 201, 20-25 (2015).
 
12. O.T. Faloye, et al, Effects of biochar and inorganic fertiliser applications on growth, yield and water use efficiency of maize under deficit irrigation, Agricultural Water Management, 217, 165-178 (2019).
 
13. F. Miri, J. Zamani, M. Zarebanadkouki, The Effect of Different Levels of Pistachio Harvesting Wastes Biochar on Growth and Water Productivity of Maize (Zea mays L.), Iranian Journal of Soil and Water Research, 52(1), 227-236 (2021) (In Persian).
 
14. F. Karami Niya, et al, The Effect of Spent Mushroom Compost and Its Biochar on Parsley Yield under Salinity Stress, Iranian Journal of Soil and Water Research, 50(6), 1453-1465 (2019) (In Persian).
 
15. M. Kazemizadeh, et al, Investigating the Effect of Biochar and Hydrochar (Sugar Cane Bagasse) on Yield, Water Productivity and Nitrogen Leaching in Maize Cultivation. Iranian Journal of Soil and Water Research, 51(3), 753-761 (2020) (In Persian).
 
16. X. Luo, et al, Biochar addition reduced net N mineralization of a coastal wetland soil in the Yellow River Delta, China. Geoderma, 282, 120-128 (2016).
 
17. T.J. Clough, et al, A review of biochar and soil nitrogen dynamics, Agronomy, 3(2), 275-293 (2013).
 
18. M.L. Cayuela, et al, Biochar's role in mitigating soil nitrous oxide emissions: A review and meta-analysis, Agriculture, Ecosystems & Environment, 191, 5-16 (2014).
 
19. H.P. Schmidt, European biochar certificate-guidelines for a sustainable production of biochar, 1-17 (2016).
 
20. A. Sedmihradská, et al, Pyrolysis of wheat and barley straw, Research in Agricultural Engineering, 66(1), 8-17 (2020).
 
21. G. Haghnia, Plant Salinity Tolerance guideline, Mashad. Ferdowsi University Press, 32 (1989) (In Persian).
 
22. K.E. Saxton, W.J. Rawls, Soil water characteristic estimates by texture and organic matter for hydrologic solutions, Soil science society of America Journal, 70(5), 1569-1578 (2006).
 
23. M.K.V. Carr, Crop Yield Response to Water, FAO Irrigation and Drainage Paper 66. By P. Steduto, TC Hsiao, E. Fereres and D. Raes. Rome: Food and Agriculture Organization of the United Nations (2013).
 
24. S. Roxana, A.S. Gustavo, A. Rossella, Barley. In: Steduto, P., Hsiao, TC., Fereres, E., Raes, D. 2013. Crop Yield Response to Water. FAO Irrigation and Drainage Paper 66.: Food and Agriculture Organization of the United Nations,134-144 (2012).
 
25. T.C.S. No, Use of isotope and radiation methods in soil and water management and crop nutrition, Vienna, Austria: International Atomic Energy Agency (2001).
 
26. Water & Soil Research Institute, No. 467, 255 (2008) (In Persian).
 
27. A. Gathorne-Hardy, J. Knight, J. Woods, Biochar as a soil amendment positively interacts with nitrogen fertiliser to improve barley yields in the UK. In IOP Conference Series, Earth and Environmental Science, 6(37) (2009) IOP Publishing.
 
28. J. Horák, V. Šimanský, E. Aydin, Benefits of biochar and its combination with nitrogen fertilization for soil quality and grain yields of barley. wheat and corn, Journal of Elementology, 25(2), 443-458 (2020).
 
29. E. Kondrlova, J. Horak, D. Igaz, Effect of biochar and nutrient amendment on vegetative growth of spring barley (’Hordeum vulgare’ L. var. Malz), Australian Journal of Crop Science, 12(2), 178–184 (2018).
 
30. T.F. Abbruzzini, Dynamic biochar effects on nitrogen use efficiency, crop yield and soil nitrous oxide emissions during a tropical wheat-growing season, Journal of Environmental Management, 252, 109638 (2019).
 
31. Z. Wang, et al, Biochar increases 15N fertilizer retention and indigenous soil N uptake in a cotton-barley rotation system, Geoderma, 357, 113944 (2020).
 
32. X. Chen, Biochar as a tool to reduce environmental impacts of nitrogen loss in water-saving irrigation paddy field, Journal of Cleaner Production, 290, 125811 (2021).
 
33. M. Wang, et al, Steel slag and biochar amendments decreased CO2 emissions by altering soil chemical properties and bacterial community structure over two-year in a subtropical paddy field, Science of The Total Environment, 740, 140403 (2020).
 
34. M. Brtnicky, A critical review of the possible adverse effects of biochar in the soil environment, Science of The Total Environment, 796, 148756 (2021).
 
35. C. Zörb, C.M. Geilfus, K.J. Dietz, Salinity and crop yield, Plant Biology, 21, 31-38 (2019).
 
36. M.A. ÇULLU, Estimation of the effect of soil salinity on crop yield using remote sensing and geographic information system, Turkish Journal of Agriculture and Forestry, 27(1), 23-28 (2003).
مجله علوم، مهندسی و فناوری هسته‌ای
دوره 43، شماره 1 - شماره پیاپی 99
فروردین 1401
صفحه 47-56
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