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برآورد اثر کشت مخلوط بر تولید علوفه و شاخص کارآئی ماشک (Vicia narbonensis L.) و جو (Hordeum vulgare L.) در شرایط تداخل علفهای هرز | ||
علوم گیاهان زراعی ایران | ||
مقاله 2، دوره 49، شماره 3، آذر 1397، صفحه 13-23 اصل مقاله (670.28 K) | ||
نوع مقاله: مقاله پژوهشی | ||
شناسه دیجیتال (DOI): 10.22059/ijfcs.2017.219998.654214 | ||
نویسندگان | ||
خسرو عزیزی* ؛ علیرضا دارائی مفرد؛ بهروز نصیری؛ محمد فیضیان | ||
دانشگاه لرستان | ||
چکیده | ||
آزمایش مزرعه ای بهمنظور بررسی اثر کشت مخلوط و علفهای هرز، در مزرعه تحقیقاتی دانشکده کشاورزی دانشگاه لرستان در دو سال زراعی (95-1394 و 94-1393) با دو گیاه لگوم و غله (ماشک برگ درشت و جو رقم آبیدر) در قالب سیستم مخلوط افزایشی (Additive Series Intercropping) بصورت فاکتوریل 5×4 در قالب طرح بلوکهای کامل تصادفی با سه تکرار و در یک مکان بصورت دیم اجراء شد، تیمارها شامل چهار سطح علف هرز (وجین کامل، یکبار وجین، دو بار وجین و عدم وجین) و سطوح مختلف اجزای مکمل مخلوط در 5 سطح، 40:100 (جو:ماشک)، 70:100، 100:100، 0:100 (کشت خالص جو) و 100:0 (کشت خالص ماشک)، بود. در همه برهمکنشها با افزایش تعداد دفعات وجین (کنترل علف های هرز) این عملکرد بیشتر شد.کمترین تعداد علف هرز (در متر مربع) از سال اول و دوم با مخلوط 70:100 (جو:ماشک برگ درشت) معادل 21 و 35/21 بدست آمد، کشت خالص جو بیشترین وزن علفهای هرز و کمترین کنترل را به عهده داشت (54/34 گرم/متر مربع)، از طرفی سطوح مخلوط، ترکیب 40:100 و 70:100 بیشترین کاهش وزن خشک کل علفهای هرز را به خود اختصاص دادند (56/24 و 77/23 گرم در متر مربع). بنابراین، در سطوح مذکور (متعادل کشت مخلوط) راندمان کنترل علفهای هرز در سال دوم بیش از سال اول بود. همچنین، با کاهش سهم ماشک از 100 به 70 و 40 درصد، بهره برداری از محیط نیز کاهش یافت و حداقل نسبت برابری زمین کل (LERt) در سال دوم و سطوح مختلف علف هرز به نسبت بذری 40:100 تعلق داشت. | ||
کلیدواژهها | ||
مخلوط افزایشی؛ کشت خالص؛ کنترل بیولوژیک | ||
عنوان مقاله [English] | ||
Estimation of the effect of intercropping on hay production and efficiency indices of vetch (Vicia narbonensis L.) and barley (Hordeum velgare L.) in weeds interference | ||
نویسندگان [English] | ||
Khosro Azizi؛ Ali Reza Daraeimofrad؛ Behrouz Nasiri؛ Mohammad Feizian | ||
Lorestan University | ||
چکیده [English] | ||
The field experiment to study the effects of intercropping on weed control, in the Agricultural Research Station of Lorestan University of 2014-15 and 2015-16 in 4×5 factorial randomized complete block design with three replications, in two consecutive years in one place was carried out on dry land. In this experiment, two plants (legume and cereal or broad leaf vetch and barley cultivar Abidar) in the form of additive series intercropping system with four levels of weed (weeding, once weeding, double weeding and non-weeding) and complementary components of intercropping in five levelsThe lowest number of weeds (in square meters) of first and second year with a mixture of 100: 70 (barley:vetch) was equivalent to 21 and 21.35, sole cropping of barley was the lowest greatest weight weed control (34.54 g/m²). the levels mix, combination of 100: 40 and 100: 70 most of the weeds dry weight, respectively (24.56 and 23.77 gr/m2). So, at the mentioned levels (intercropping balanced) efficiency of weed control in the second year was than the first year. Also, by reducing the share of vetch from 100 to 70 and 40 percent, the exploitation of the environment reduced and minimum LERt in the second year and different levels of weed was belonged to 40:100 seed ratio. | ||
کلیدواژهها [English] | ||
Additive Series Intercropping, Sole Intercropping, biological control | ||
مراجع | ||
1. Agegnehu, G., Ghizaw, A. & Sinebo W. (2006). Yield performance and land use efficiency of barley and fababean mixed cropping in Ethiopian highlands. European Journal Agronomy. 25: 202-207.
2. Akbari, N., Daraeimofrad, A. R., Hosseinian, S. H., Zaremanesh, H. & Kakoolvand, E. (2014). The effect of the different densities of intercropping triticale and common vetch on the hay yield of crops and weed populations under dryland conditions. The first Conference on new findings on the environment and agricultural ecosystem. Tehran University, the Institute of energy and environment. 523. (In Farsi).
3. Asgharipour, M. & Rafiei, M. (2010). Intercropping of Isabgol (Plantago Ovata L.) and lentil as influenced by drought stress. American-Eurasian Journal of Sustainable Agriculture. 4(3), 341-348.
4. Azizi, Kh., Daraeimofrad, A. R., Heidari, S., Amini Dehaghi, M. & Kahrizi, D. (2011). A study on the qualitative and quantitative traits of barley (Hordeum vulgare L.) and narbon vetch (Vicia narbonensis L.) in intercropping and sole cropping system under the interference and control of weeds in dry land farming conditions of Iran. African Journal of Biotechnology. Vol. 10(1), pp. 13-20, 3 January, 2011. Available online at http://www.academicjournals.org/AJB.
5. Azizi, Kh., Hosseinian, S. H., Zaremanesh, H., Daraeimofrad, A. R. & Kakoolvand, E. (2014). A study on the possibility of harnessing the weeds and hay production in barley and rough pea intercropping. The first Conference on new findings on the environment and agricultural ecosystem. Tehran University, the Institute of energy and environment. 519. (In Farsi).
6. Banik, P., Midya, A., Sarkar, B. K. & Ghose, S. S. (2006). Wheat and chickpea intercropping systems in an additive series experiment: advantages and weed smothering. European Journal of Agronomy.24: 325- 332.
7. Bond, W. & Grundy, A. C. (2000). Non-chemical weed management in organic farming systems. Weed Research. 41, 383–405.
8. Dhima, K. V., Lithourgidis, A. S., Vasilakoglu, I. B. & Dordas, C. A. (2006). Competition indices of common vetch and cereal intercrops in two seeding ratio. Field Crops Research. Vol. 100, 2–3, 249–256.
9. Egbe, O.M. & Adeyemo, M. O. (2007). Estimation of the effect of intercropped pigeon pea on the yield and yield components of maize in southern Guinea Savannah of Nigeria. African. Journal of Agriculture. Research. 2(12): 667-677.
10. Epidi, T.T., Bassey, A.E. & Zuofa, K. (2008). Influence of intercrops on pest’s population in upland rice (Oriza sativa L.). African Journal Environment Science Technology. 2: 438– 441.
11. Eskandari, H. Ghanbari, A. & Javanmard, A. (2009). Intercropping of cereals and legumes for forage production. Notulae Scientia Biological, 1: 07-13.
12. Evans J, Mcneill AM, Unkovich MJ, Fettell NA and Heenan DP. (2001). Net nitrogen balances for cool-season grain legume intercropping and contributions to wheat nitrogen uptake: a review. Australian JournalAgriculture. 41: 347-359.
13. Geren, H., Avcioglu, R., Soya, H. & Kir, B. (2008). Intercropping of corn with cowpea and bean: Biomass yield and silage quality. Biotechnology Research. 22: 4100-4104.
14. Ghanbari, A. & Lee, H. C. (2003). Intercropped wheat (Triticum aestivum L.) and bean (Vicia faba L.) as a wholecrop forage: effect of harvest time on forage yield and quality. Grass and Forage Science. 58(1): 28-36.
15. Gomes, P. & Gurevitch, J. (2005). Weed community responses in a corn-soybean intercrop. Opulus Press. 1: 281-288.
16. Hagh, S., David, E.C. & Sharon, A. (2002). The impact of intercropping annual, sava, snail medic on corn production. Agronomy Journal. 94: 917-924.
17. Hamzei, J. & Seyedi, M. (2013). Effect of Intercropped Barley on Weed Suppression in Chickpea-Barley Intercropping Systems. International journal of Agronomy and Plant Production. Vol., 4 (5), 884-891. Available online at http:// www.ijappjournal.com.
18. Hamzei, J., Seyedi, M., Seyedi, G. & Abootalebian, M.A. (2012). The Effect of Additive Intercropping on Weed Suppression, Yield and Yield Component of Chickpea and Barley. Production and processing of agricultural and horticultural crops. 2(3): 43-56. (In Farsi).
19. Hauggaard-Nielsen, H., Andferson, M. K., Jqrnsgaard, B. & Jensen, E. S. (2005). Density and relative frequency effects on competitive interactions and resource use in pea-barley intercrops. Field Crop Research. 95: 256-267.
20. Jeyabal, A. & Kuppuswamy, G. (2001). Recycling of organic wastes for the production of vermicomposting and its response in rice-legume cropping systems and soil fertility. Heriana Journal Agronomy. 15: 153–170.
21. Liebman, M. & Davis, A. S. (2000). Integration of soil, crop and weed management in low-external-input farming systems. Weed Research. 40. 27–47.
22. Maingi, M,J., Shisanya, A.C., Gitonga, M,N. & Hornetz, B. (2001). Nitrogen fixation by common bean (Phaseolus vulgaris L.) in pure and mixed stands in semi-arid South East Kenya. European Journal Agronomy. 14: 1–12.
23. Marer, S. B., Lingaraju, B.S. & Shashidhara, G.B. (2007). Productivity and economics of maize and pigeonpea intercropping under rainfed condition in northern transitional zone of karnataka. Karnataka Journal. Agriculture. Science. 20(1): 1-3.
24. Midya, A., Bhattacharjee, K., Ghose, S.S. & Banik, P. (2005). Deferred seeding of blackgram (Phaseolus mungo L.) in rice (Oryza sativa L.) field on yield advantages and smothering of weeds. Journal. Agronomy. Crop Science. 191, 195–201.
25. Mohammadi, H., Pirdashti, H., Yazdani, M. & Abbasian, A. (2012). Changes of weed abundance and diversity in barley (Hordeum vulgare) and fenugreek (Trigonella foenum-graecum) intercropping. International journal of Agronomy and Plant Production. Vol., 3 (S), 788-793,. Available online at http:// www.ijappjournal.com.
26. Molatudi, R.L. & Mariga I. K. (2012). Grain yield and biomass response of a maize/dry bean intercrop to maize density and dry bean variety. African Journal of Agricultural Research. 7:3139-3146.
27. Najafi, N., Mostafaei, M., Dabagh, A. & Avestan, S.h. (2013). Effect of Intercropping and Farmyard Manure on the Growth, Yield and Protein Concentration of Corn, Bean and Bitter Vetch. Agricultural Science and Sustainable Production Journal. Vol 23 (1). 99-115.
28. Newton, A. C., Begg, G. S. &Swanston J. S. (2009). Deployment of diversity for enhanced crop function. Annals of Applied Biology. Vol. 154 p. 309–322.
29. Ofori, F. & Stern, W. R. (1987). Cereal-Legum intercropping systems. Agronomy Journal. 41: 41-90.
30. Olufemi, O. R., Pitan, J. & Odebiyi, A. (2001). The effect of intercropping with maize on the level of infestation and damage by pod-sucking bugs in cowpea. Journal. Crop Protection. 20: 367-372.
31. Poggio, S. L. (2005). Structure of weed communities occurring in monoculture and intercropping of field pea and barley. Elsevier. Science direct. 109: 48-58.
32. Tsubo, M., Walker, S. & Ogindo, H. O. (2004). model of cereal-legum intercropping systems for semi-arid regions ІІ. Model application. Field Crop Research. 93: 23-33.
33. Verschwele, A . (2005). Weed control with herbicides – chances and risks for organic farming. In: Beiträge zur 8. Wissenschaftstagung zum Ökologischen Landbau, 1.-4.März (eds JHeß & GRahmann). 291–294. Kassel University Press, Kassel.
34. Yadollahi, P., Borjiabad, A. R., Khaje, M., Asgharipour, M. R. & Amiri, A. (2014). Effect of intercropping on weed control in sustainable agriculture. International Journal of Agriculture and Crop Sciences. Vol. 7 (10), 683-686, 2014.
35. Zhang, X., Huang, G., Bian, X. & Zhao, Q. (2013). Effects of root interaction and nitrogen fertilization on the chlorophyll content, root activity, photosynthetic characteristics of intercropped soybean and microbial quantity in the rhizosphere. Plant, Soil and Environment. 59: 80–88.
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