Water Capture, and Use Efficiency and Productivity in Sole and Intercropping of Rapeseed (Brassica napus L.), Bean (Phaseolus vulgaris L.) and Corn (Zea mays L.)

Document Type : Research Article

Authors

Abstract

In order to evaluate water capture and use efficiency and also productivity in sole and intercropping of three crops Rapeseed, Bean and Corn, an experiment was conducted in Mashhad in the growing season of 2007-2008. In this investigation six treatments including three sole cropping of the three crops (rapeseed sown in 22 September 2007, bean and corn in 29 April 2008) and three intercropping including double cropping (simultaneous sowing of corn and bean in 29 April 2008), two stage-relay intercropping of rapeseed, corn and bean (rapeseed in 22 September 2007, bean and corn in 29 April 2008) and finally three stage-relay intercropping of rapeseed, corn and bean (rapeseed sown in 22 September 2007, bean in 8 April 2008 and corn in 29 April 2008) were arranged in a complete randomized block design with three replications. Results showed that in general, cropping combination affected water capture and use efficiency and also water productivity (p≤0.01). Among intercropping treatments, two stage-relay intercropping showed the highest capture efficiency (0.43), three stage-relay intercropping had the highest water use and productivity in terms of biological yields (1.82 and 0.73 g/m2/mm, respectively) and double cropping showed the highest water use efficiency and productivity in terms of seed yield (0.43 and 0.17 g/m2/mm, respectively). Among sole cropping treatments, rapeseed showed the highest capture efficiency (0.26), use efficiency and productivity in terms of biological yields (6.82 and 1.75 g/m2/mm, respectively) and corn showed the highest use efficiency and productivity in terms of seed yield (1.5 and 0.35 g/m2/mm, respectively). In general, two stage-relay intercropping for capture efficiency, sole cropping of rapeseed for use efficiency and productivity in terms of biological yield, and sole cropping of corn for use efficiency and productivity in terms of seed yield were superior than others. However, it seems that such combinations of crops for different reasons may not perform satisfactory results because of shading effect of rapeseed on young seedlings of corn and bean. Therefore, the design of these experiments should be altered in such a way to achieve in shortest overlapping of the growth of rapeseed with companion crops.

Keywords


1- اهدایی، ب. 1373. بازدهی مصرف آب و اجزای آن در گندم بهاره. چکیده مقالات دومین کنگره علوم زراعت واصلاح نباتات ایران، تهران.
2- سلطانی، ا.، و ا. فرجی. 1386. رابطه آب خاک و گیاه (چاپ اول). جهاد دانشگاهی مشهد، مشهد.
3- علیزاده، ا. و غ. کمالی. 1386. نیاز آبی گیاهان در ایران. انتشارات آستان قدس رضوی.
4- کوچکی، ع. و ا. سلطانی. 1377. اصول و عملیات کشاورزی در مناطق خشک (ترجمه). انتشارات نشر آموزش کشاورزی، مشهد.
5- مظاهری، د. 1373. زراعت مخلوط. چاپ اول. انتشارات دانشگاه تهران، تهران.
6- نصیری محلاتی، م.، ع. کوچکی، پ. رضوانی مقدم و ع. بهشتی. 1383. اگرواکولوژی. چاپ دوم. انتشارات دانشگاه فردوسی مشهد.
7- وفابخش، ج. 1386. مطالعه جنبه های اکوفیزیولوژیک گیاه زراعی کلزا (Brassica napus L.) در شرایط تنش خشکی. پایان نامه دوره دکتری، دانشکده کشاورزی دانشگاه فردوسی مشهد.
8- Araus, J. L., G. A. Salfer, M. P. Reynold, and C. Royo. 2002. Plant breeding and drought in C3 cereals: What should we breed for? Annuals of Botany 89: 925-940.
9- Boyer, J. S. 1982. Plant productivity and environment. Science 218: 443-448.
10- Caviglia, O. P., V.O. Sadras, and F. H. Andrade. 2004. Intensification of agriculture in the south-eastern Pampas I. Capture and efficiency in the use of water and radiation in double-cropped wheat–soybean. Field Crop Research. 87: 117-129.
11- Condon, A. G., R. A. Richards, G. J. Rebetzek, and G. D. Farquhar. 2004. Breeding for high water use efficiency. Journal of Experimental Botany 55: 2447-2460.
12- Ehdaie, B. 1995. Variation in water use efficiency and its components in wheat ΙΙ, Pot and field experiments. Crop Science 35: 1617-1629.
13- Fukai, S. 1993. Intercropping-bases of productivity. Field Crop Research. 34: 239–245.
14- Howell, T. A. 2001. Enhancing water use efficiency in irrigated Agriculture. Agronomy Journal. 93: 281-289.
15- Hulugalle, N. R., and R. Lal. 1986. Soil water balance of intercropped maize and cowpea grown in tropical hydromorphic soil Western Nigeria. Agronomy Journal 74:86-90.
16- Lal, R. 2000. Soil management in the developing countries. Soil Science 105: 57-72.
17- Molden, D., T. Oweis, P. Steduto, J. W. Kijne, M. A. Hanjra, and P. S. Bindraban. 2007. Pathways for increasing agricultural water productivity. In: Chapter 7 in Water for Food, Water for Food, Water for Life: A Comprehensive Assessment of Water Management in Agriculture, International Water Management Institute, London, Earthscan, Colombo.
18- Nangia, V., C. De Fraiture, and H. Turral. 2008. Water quality implications of raising crop water productivity. Agricultural Water Management 95 (7): 825-835.
19- Passioura, J. B. 2006. Increasing crop productivity when water is scarce-from breeding to field management. Agricultural Water Management 80: 176-196.
20- Payne, W. A. 1997. Managing yield and water use of pearl millet in the Sahel. Agronomy Journal 89: 481-490.
21- Richards, R. A., G. J. Rebetzke, A. G. Condon, and A. F. Van Herwaarden. 2002. Breeding opportunities for increasing the efficiency of water use and crop yield in temperate cereals. Crop Science 42: 111-121.
22- Ritchie, J. T., and B. Basso. 2007. Water use efficiency is not constant when crop water supply is adequate or fixed: the role of agronomic management. European Journal of Agronomy 28 (3):273-281.
23- Schott, J. J., A. Bar-Hen, H. Monod, and F. Blout. 1994. Competition between winter rape cultivars under experimental conditions. Cahiers dۥEtudes Rech. France. Agric. 3: 377-383.
24- Sekiya, N., and K. Yano. 2004. Do pigeonpea and sesbania supply ground water to intercropped maize through hydraulic lift? Hydrogen stable isotope investigation of xylem waters. Field Crop Research 86: 167-173.
25- Stanhill, G. 1986. Water use efficiency. Adv. in Agron. 39: 53-85.
26- Tsubo, M., S. Walker, and E. Mukhala. 2001. Comparisons of radiation use efficiency of mono/intercropping system with different row orientation. Field Crop Research 71: 17-29.
27- Tsubo, M., S. Walker, and H. O. Ogindo. 2005. A simulation model of cereal- legume intercropping systems for semi-arid regions I. model development. Field Crop Research 93: 10-22.
28- Vandermeer, J., M. Van Noordwijk, J. Anderson, C. Ong, and I. Perfecto. 1998. Global change and multi-species agroecosystems: concepts and issues. Agriculture, Ecosystems and Environment 67: 1–22.
29- Walker, S., and H. O. Ogindo. 2003. The water budget of rainfed maize and bean intercrop. Physics and Chemistry of the Earth 28: 919-926.
30- Zougmor, R., F. N. Kambou, K. Ouattara, and S. Guillobez. 2000. Sorghum-Cowpea intercropping; an effective technique against run off and soil erosion in the Sahel (saria, Burkina Faso). Arid Land Research and Management 14: 329-342.
CAPTCHA Image