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میرزاوند, جهانبخش, شهبازی, خسرو, مجیدی, عزیز, کاظمی, زهرا. (1404). تأثیر فشردگی خاک بر عملکرد محصول و ارزش اقتصادی زمین. سامانه مدیریت نشریات علمی, 13(1), 59-78. doi: 10.22092/lmj.2025.364922.359
جهانبخش میرزاوند; خسرو شهبازی; عزیز مجیدی; زهرا کاظمی. "تأثیر فشردگی خاک بر عملکرد محصول و ارزش اقتصادی زمین". سامانه مدیریت نشریات علمی, 13, 1, 1404, 59-78. doi: 10.22092/lmj.2025.364922.359
میرزاوند, جهانبخش, شهبازی, خسرو, مجیدی, عزیز, کاظمی, زهرا. (1404). 'تأثیر فشردگی خاک بر عملکرد محصول و ارزش اقتصادی زمین', سامانه مدیریت نشریات علمی, 13(1), pp. 59-78. doi: 10.22092/lmj.2025.364922.359
میرزاوند, جهانبخش, شهبازی, خسرو, مجیدی, عزیز, کاظمی, زهرا. تأثیر فشردگی خاک بر عملکرد محصول و ارزش اقتصادی زمین. سامانه مدیریت نشریات علمی, 1404; 13(1): 59-78. doi: 10.22092/lmj.2025.364922.359

تأثیر فشردگی خاک بر عملکرد محصول و ارزش اقتصادی زمین

مدیریت اراضی
مقاله 4، دوره 13، شماره 1، مرداد 1404، صفحه 59-78    اصل مقاله (1.64 M)
نوع مقاله: مروری
شناسه دیجیتال (DOI): 10.22092/lmj.2025.364922.359
نویسندگان
جهانبخش میرزاوند1؛ خسرو شهبازی2؛ عزیز مجیدی3؛ زهرا کاظمی* 4
1استادیار پژوهشی، بخش تحقیقات خاک و آب، مرکز تحقیقات و آموزش کشاورزی و منابع طبیعی استان فارس، سازمان تحقیقات، آموزش و ترویج کشاورزی، شیراز، ایران
2دانشیار پژوهشی، موسسه تحقیقات جنگلها و مراتع کشور، سازمان تحقیقات، آموزش و ترویج کشاورزی، تهران، ایران.
3دانشیار پژوهشی، بخش تحقیقات خاک و آب، مرکزتحقیقات و آموزش کشاورزی و منابع طبیعی استان آذربایجان غربی، سازمان تحقیقات، آموزش و ترویج کشاورزی، ارومیه ، ایران.
4دکتری فیزیک و حفاظت خاک، دانشگاه تبریز، دانشکده کشاورزی، گروه علوم و مهندسی خاک، ایران.
چکیده
کاهش عملکرد محصول و کارایی مصرف منابع، اثرات نامطلوب مستقیم و غیرمستقیم فشردگی خاک بوده که بر سودآوری سامانه ­های کشاورزی تأثیر می­گذارد. فشردگی خاک با کاهش تخلخل تهویه­ ای، افزایش جرم مخصوص ظاهری (Db)، مقاومت مکانیکی خاک و کاهش میزان تخلخل کل، ساختمان خاک را تحت تاثیر قرار می­دهد. مقاله مروری حاضر به بررسی مطالعات به انجام رسیده در خصوص ارزیابی اثر سامانه­ های مختلف خاک­ورزی بر میزان فشردگی خاک و تاثیر آن بر عملکرد و ارزش اقتصادی زمین پرداخته است. پژوهش­ ها نشان می­دهد بین 80-70 درصد فشردگی خاک  طی اولین عبور ماشین­آلات کشاورزی بر روی زمین زراعی اتفاق می­افتد و کاهش عملکرد محصول ناشی از فشردگی خاک در منابع مختلف در محدوده 75-5 درصد گزارش گردیده است. در یک پژوهش، میانگین ضررهای مالی ناشی از افزایش فشردگی خاک در هر هکتار زمین زراعی برای اوکراین و لیتوانی به ترتیب 49 و 13 یورو در هکتار در سال پیش­بینی گردید. خسارت مالی ناشی از فشردگی خاک در اثر پخش کود مایع با تانکر سنگین با وزن بیش از 18 تن و فشار بیش از 200کیلوپاسکال روی خاک مرطوب در اوایل بهار در کانادا نیز 30 تا 300 دلار در هکتار برآورد شد و افزایش فشار چرخ­های ادوات کشاورزی از یک مگاپاسکال به نه مگاپاسکال در سوئد مقدار درآمد خالص زمین زراعی را 25 درصد کاهش داد. بررسی­ها بیانگر این است که که بکارگیری کم­خاک­ورزی منجر به صرفه­ جویی اقتصادی، افزایش بهره­وری انرژی و کاهش انتشار گازهای گلخانه­ ای می­گردد و در اغلب موارد افزایش عملکرد محصول در واحد سطح را به دنبال داشته است.
کلیدواژه‌ها
تخلخل تهویه‌ای؛ جرم مخصوص ظاهری؛ ساختار خاک؛ گازهای گلخانه‌ای؛ مقاومت مکانیکی خاک
عنوان مقاله [English]
Impacts of soil compaction on crop yield and economic value of arable lands
نویسندگان [English]
Jahanbakhsh Mirzavand1؛ Khosrow Shahbazi2؛ Aziz Majidi3؛ Zahra Kazemi4
1Assistant Prof., Soil and Water Research Department, Fars Agricultural and Natural Resources Research and Education Center, AREEO, Zarghan, Iran.
2Associate Prof., Forests and Rangelands Research Institute, Agricultural and Natural Resources Research and Education Organization, AREEO, Tehran, Iran.
3Associate Prof., Soil and Water Research Department, West Azerbaijan, Agricultural and Natural Resources Research and Education Center, AREEO, Uromia, Iran.
4PhD in Soil Physics and Conservation, Soil Science Department, Faculty of Agriculture, University of Tabriz, Iran.
چکیده [English]
Declining crop yield and resource efficiency are the direct and indirect adverse effects of soil compaction, which affect the profitability of agricultural systems. Soil compaction impresses soil structure by reducing air-filled porosity, increasing soil bulk density and mechanical resistance, and reducing total porosity. The present review article explores the various studies focused on the effects of different tillage systems on soil compaction and their impacts on yield and economic value of land. The studies reviewed show that between 70-80% of soil compaction occurs during the first passage of agricultural machinery on land and that reduced crop yield due to soil compaction reportedly falls within the range of 5-75%. One study predicted the average financial losses due to soil compaction in Ukraine and Lithuania to be 49 and 13 euros per hectare per year, respectively. The financial cost of soil compaction caused by spreading liquid fertilizer weighing more than 18 Mg with a heavy tanker exerting a pressure of more than 200 kPa on wet soil in early spring in Canada was reportedly estimated at 30 to 300 dollars per hectare and the increase in wheel loads of agricultural machines from 1 MPa to 9 MPa in Sweden reduced the net income of agricultural land by 25%. This is while the use of a No-Tillage system has been reported to lead to economic savings, increased energy efficiency, and reduced greenhouse gas emissions, which in most cases, leads to an increase in crop yield per unit area.
کلیدواژه‌ها [English]
Air filled porosity, Bulk density, Soil structure, Greenhouse gases, and Soil mechanical resistance
مراجع
  1. Alakukku, L., 2000. Response of annual crops to subsoil compaction in a field experiment on clay soil lasting 17 years. Advances in Geoecology. 32, pp.205–208.
  2. Bhatta, P., Girib, P.R. and Naparic, B., 2024. Soil compaction and its impact on soil properties, microbiome, greenhouse gas emission and root growth. Big Data in Agriculture (BDA) 6(1). 66-69. http://doi.org/10.26480/bda.01.2024.66.69.
  3. Biberdzic, M., Barac, S., Lalevic, D., Djikic, A., Prodanovic, D., and Rajicic, V., 2019. Influence of soil tillage system on soil compaction and winter wheat yield. Chilean Journal of Agriculture Research, 80. pp. 80–89.
  4. Bicki, T.J., and Siemens, J.C., 1990. Crop response to wheel compaction. In Proc. ASAE Summer Meeting, Columbus. OH, pp. 24-27.
  5. Botta, G.F., Tolon-Becerra, A., Lastra-Bravo, X., and Tourn, M., 2010. Tillage and traffic effects (planters and tractors) on soil compaction and soybean (Glycine max L.) yields in Argentinean pampas. Soil and Tillage Research, 110 (1), pp. 167–174.
  6. Butorac, A., 1982. Response of summer oats (Avena sativa L.) and winter rye (Secale cereale L.) in model experiments to soil compaction and fertility. Znan. Smotra. 59, pp. 225-232.
  7. Cannell, R.Q. 1977. Soil aeration and compaction in relation to root growth and soil management. Applied Biology, 2, pp. 1–86.
  8. Carr, M. K. V., and Dodds, S. M., 1983. Some effects of soil compaction on root growth and water use of lettuce. Agricukture, 19, pp. 117-130.
  9. Copec, K., Filipovic, D., Husnjak, S., Kovacev, I., and Kosutic, S., 2015. Effects of tillage systems on soil water content and yield in maize and winter wheat production. Plant, Soil and Environment, 61(5), pp.213-219.
  10. Croissant, R.L., Schwartz, H.F. and Ayers. P.D., 1988. Soil compaction losses in pinto beans. Annual Report of the Bean Improvement Cooperative. 31, pp.58-61. Colorado State University, Fort Collins, CO.
  11. Dai, X., Li, Y., Ouyang, Z., Wang, H., and Wilson, G.V., 2013. Organic manure as an alternative to crop residues for no-tillage wheat-maize systems in North China Plain. Field Crops Research. 149(1), pp. 141-148. https://doi.org/10.1016/j.fcr.2013.04.027.
  12. Drewry, J.J., Littlejohn, R.P., Paton, R.J., Singleton, P.L., Monaghan, R.M., and Smith, L.C., 2004. Dairy pasture responses to soil physical properties. Australian Journal of Soil Research, 42, pp. 99–105. https://doi.org/10.1071/SR03055
  13. Flocker, W.J., and Nielsen, D.R., 1962. The absorption of nutrient elements by tomatoes associated with levels of bulk density. Soil Science Society of America Journal 26, pp.183-186. https://doi.org/10.2136/sssaj1962.03615995002600020025x.
  14. Frene, J.P., Pandey, B.K. and Castrillo, G., 2024. Under pressure: elucidating soil compaction and its effect on soil functions. Plant and Soil, pp.1-12.
  15. Gliñski, J. and Lipiec, J., 1990. Soil Physical Conditions and Plant Roots. CRC Press, Boca Raton, FL, U.S.A.
  16. Galambošová, J., Macák, M., Rataj, V., Antille, D.L., Godwin, R.J., Chamen, W.C.T., and Chlpík, J., 2017. Field evaluation of controlled traffic farming in Central Europe using commercially available machinery. Transactions of the ASABE. 60(3), pp.657–669. https://doi: 10.13031/trans.11833
  17. Gao, H., Song, X., Wu, X., Zhang, N., Liang, T., Wang, Z., Yu, X., Duan, C., Han, Z. and Li, S., 2024. Interactive effects of soil erosion and mechanical compaction on soil DOC dynamics and CO2 emissions in sloping arable land. Catena, 238, p.107906.
  18. Gregorich, E.G., Lapen, D.R., Ma, B.L., McLaughlin, N.B., and Vanden Bygaart, A.J., 2011. Soil and crop response to varying levels of compaction, nitrogen fertilization, and clay content. Soil Science Society of America Journal. 75(4), pp. 1483–1492. https://doi.org/10.2136/sssaj2010.0395
  19. Godwin, R.J., Misiewicz, P.A., Smith, E.K., Millington, W.A.J., White, D.R., Dickin, E.T., and Chaney, K., 2017. Summary of the effects of three tillage and three traffic systems on cereal yields over a four-year rotation. Aspects of Applied Biology. 134, pp. 233–241. https://doi:10.13031/aim.201701652.
  20. Hakanson, I., 2005. Machinery-induced compaction of arable soils: Incidence–consequences–counter measures. In Reports from the Division of Soil Management; Swedish University of Agricultural Sciences: Uppsala, Sweden; no 109.
  21. Hakansson, I., Voorhees, W.B. and Riley, H., 1988. Vehicle and wheel factors influencing soil compaction and crop response in different traffic regimes. . Soil and Tillage Research. 11, pp. 239-282. https://doi.org/10.1016/0167-1987(88)90003-7.
  22. Hebblethwaite, P.D., and McGowan, M., 1980. The effects of soil compaction on the emergence, growth and yield of sugar beet and peas. Journal of the science of food and agriculture. 31, pp.1131-1141. https://doi.org/10.1002/jsfa.2740311103.
  23. Hu, W., Drewry, J., Beare, M., Eger, A. and Müller, K., 2021. Compaction induced soil structural degradation affects productivity and environmental outcomes: A review and New Zealand case study. Geoderma, 395, p.115035.
  24. Iler, G.S. and Stevenson, C.K., 1991. The effect of soil compaction on the production of processing vegetables and field crops- A review. Ridge Town College of Agricultural Technology, soils section, Ridge town, Ontario, Canada.

 http://hdl.handle.net/10214/14039

  1. Jamali, H.; Nachimuthu, G., Palmer, B.; Hodgson, D., Hundt, A. Nunn, C., and Braunack, M., 2021. Soil compaction in a new light: Know the cost of doing nothing—a cotton case study. Soil and Tillage Research, 213, pp. 105-158.

 https://doi.org/10.1016/j.still.2021.105158.

  1. Katoch, K.K., Aggarwal, G.C., and Garg, F.C., 1983. Effect of nitrogen, soil compaction and moisture stress on nodulation and yield of soybean. Journal of. Indian Society Soil Science, 31, pp. 215-225.
  2. Kayombo, B., and Lal, R., 1994. Responses of tropical crops to soil compaction. , pp.287–316. In BD Soane and C van Ouwerkerk (eds). Soil compaction in crop production. Elsevier Science Publishers B.V.: Amsterdam, Netherlands.

 https://doi.org/10.1016/B978-0-444-88286-8.50021-0.

  1. Kik, M.C., Claassen, G.D.H., Ros, G.H., Meuwissen, M.P.M., Smit, A.B. and Saatkamp, H.W., 2024. FARManalytics–A bio-economic model to optimize the economic value of sustainable soil management on arable farms. European Journal of Agronomy, 157, p.127192.
  2. Lepore, E., Schmidt, O., Fenton, O., Tracy, S., Bondi, G. and Wall, D.P., 2024. Traffic induced compaction and physical quality of grassland soil under different soil moisture deficits. Soil and Tillage Research, 244, p.106205.
  3. Lindemann, W.C., Ham, G.E. and Randall G.W., 1982. Soil compaction effects on soybean nodulation, N2 (C2H4) fixation and seed yield. Journal, 74, pp.307- 311. https://doi.org/10.2134/agronj1982.00021962007400020012x.
  4. Lipiek, J., Medvedev, V.V., Birkas, M., Dumitru, E. Lyndina, T.E., Rousseva, S. and Fulajtár, E., 200 Effect of soil compaction on root growth and crop yield in Central and Eastern Europe. International Agrophysics, 17, pp. 61–69.
  5. Mielke, L.N., and Jones, A.J., 1990. Effect of soil compaction and subsoiling on corn and soybean yield. Abstr. 321.
  6. Mileusnić, Z.I., Saljnikov, E., Radojević, R.L. and Petrović, D.V., 2022. Soil compaction due to agricultural machinery impact. Journal of Terramechanics, 100, pp.51-60.
  7. Mirzavand, J. and Moradi-Talebbeigi, R., 2020. Relationships between field management, soil compaction, and crop productivity. Archieves of Agronomy and Soil Science. 67(5), pp.675–686. https://doi.org/10.1080/03650340.2020.1749267
  8. Parvin, N., Coucheney, E., Gren, M., Andersson, H., Elofsson, K., Jarvis, N. and Keller, T., 2022. On the relationships between the sizes of agricultural machinery, soil quality and net revenues for farmers and society. Soil Security, 6, p.100044.
  9. Piccoli, I., Seehusen, T., Bussell, J., Vizitu, O., Calciu, I., Berti, A., Börjesson, G., Kirchmann, H., Kätterer, T., Sartori, F. and Stoate, C., 2022. Opportunities for mitigating soil compaction in Europe—Case studies from the soil care project using soil-improving cropping systems. Land, 11(2), p.223. https://doi.org/10.3390/land110202.23
  10. Raghavan, G.S.V., McKyes, E., and Beaulieu, B., 1978. Clay soil compaction due to wheel slip. Transactions of the American. Society of Agricultural Engineers. 21: 646-649. https:/doi: 10.13031/2013.35359.
  11. Rátonyi, T., Huzsvai, L., Nagy, J., and Megyes, A., 2005. Evaluation of soil tillage systems in maize production. Acta Agronomica Hungarica, 53, pp.53-57.

 https://doi.org/10.1556/AAgr.53.2005.1.7

  1. Reeder, R., 1990. Soil compaction update: Preparing for the 1990's. The Ohio State University, Cooperative Extension Service, Columbus, OH.
  2. Ruis, S.J., Stepanovic, S. and Blanco-Canqui, H., 2023. Intensifying a crop–fallow system: impacts on soil properties, crop yields, and economics. Renewable Agriculture and Food Systems, 38, p.e42.
  3. Shaheb, M.R., 2020. A study on the effect of tire inflation pressure on soil properties, growth and yield of maize and soybean in Central Illinois. D. thesis. Harper Adams University, Newport, Shropshire, United Kingdom.

https://hau.repository.guildhe.ac.uk/id/eprint/17769

  1. Shaheb, M.R., Misiewicz, P.A., Godwin, R.J., Dickin, E., White, D.R., Lowenberg‐DeBoer, J., Shearer, S.A. and Grift, T.E., 2023. An economic appraisal of the effect of tire inflation pressure for alternative tillage systems on a silty clay loam soil. Agronomy Journal, 115(6), pp.3144-3161.
  2. Shaheb, M.R.; Venkatesh, R., and Shearer, S.A.A., 2021. Review on the Effect of Soil Compaction and its Management for Sustainable Crop Production. Journal of. Biosystems Engineering, 46, pp. 417–439. https://doi.org/10.1007/s42853-021-00117-7.
  3. Shahzad, M., Farooq, M., Jabran, K., Yasir, T.A., and Hussain, M., 2016. Influence of various tillage practices on soil physical properties and wheat performance in different wheat-based cropping systems. International Journal of Agriculture and Biology. 18, pp. 821-829. https://doi: 10.17957/IJAB/15.0178.
  4. Smith, E.K., Misiewicz, P.A., Girardello, V., Arslan, S., Chaney, K., White, D.R., and Godwin, R.J., 2014. Effects of traffic and tillage on crop yield (winter wheat Triticum aestivum) and the physical properties of a sandy loam soil. In ASABE and CSBE/SCGAB Annual International Meeting, Montreal, Canada, July 13–16, 141912652, 1–14. St. Joseph, MI. https://doi: 10.13031/aim.20141912652.
  5. Smittle, D.A., and Williamson, R.E., 1977. Effect of soil compaction on nitrogen and water use efficiency, root growth, yield and fruit shape of pickling cucumbers. Journal of American Society Horticultural Science, 102, pp. 822-825.
  6. Soane, G.C., Godwin, R.J., and Spoor, G. 1986. Influence of deep loosening techniques and subsequent wheel traffic on soil structure. Soil and Tillage Research, 8,231-237. https://doi.org/10.1016/0167-1987(86)90336-3
  7. Stirzaker, R.J., Passioura, J.B., and Wilms, Y., 1996. Soil structure and plant growth: impact of bulk density and biopores. Plant and Soil. 185, 151–162. https://doi.org/10.1007/BF02257571.
  8. Stranks, S.N., 2006. The effects of tyre systems on the depth and severity of compaction. MSc. Thesis, Cranfield University, Cranfield, Bedford, United Kingdom.

http://hdl.handle.net/1826/1215

  1. Tietjens, F., Schröer, D. and Latacz-Lohmann, U., 2024. Farmers' preferences for the design of a slurry hosing support scheme to combat soil compaction: Insights from a discrete choice experiment in Germany. Agricultural Systems, 219, p.104030.
  2. Trouse, A.C., Jr., 1979. Effect of soil bulk density on root elongation. Zeszyty Problemowe Postepow Nauk Rolniczych, 220, pp. 349-359.
  3. Voltr, V., Wollnerová, J., Fuksa, P., and Hruška, M., 2021. Influence of Tillage on the Production Inputs, Outputs, Soil Compaction and GHG Emissions. Agriculture, 11, pp. 456. https://doi.org/10.3390/agriculture11050456.
  4. Voorhees, W.B., 1983. Relative effectiveness of till7age and natural forces in alleviating wheel-induced soil compaction. Soil Science Society of America. Journal, 47, pp. 129-133. https://doi.org/10.2136/sssaj1983.03615995004700010026x.
  5. Wang, X., Cammeraat, E.L., Cerli, C. and Kalbitz, K., 2014. Soil aggregation and the stabilization of organic carbon as affected by erosion and deposition. Soil Biology and Biochemistry, 72, pp.55-65.
  6. Wittsell, L.E., and Hobbs, J.A. Soil compaction effects on field plant growth. Agronomy. Journal, 57, pp.534-54.

https://doi.org/10.2134/agronj1965.00021962005700060005x.

  1. Wolkowski, R., and Lowery, B.,2008. Soil compaction: Causes, concerns, and cures (A3367).Madison, WI: University of Wisconsin Cooperative Extension.
  2. Zabrodskyi, A., Šarauskis, E., Kukharets, S., Juostas, A., Vasiliauskas, G., Andriušis, A., 2021. Analysis of the Impact of Soil Compaction on the Environment and Agricultural Economic Losses in Lithuania and Ukraine. 13, pp. 7762.
آمار
تعداد مشاهده مقاله: 202
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