Predmet te raziskave je bilo ovrednotenje kolobarja za pšenico in koruzo na peščenih tleh v Zgornejm Egiptu glede na obseg namakanja v posameznem kolobarju, celokupno produkcijo in učinkovitost izrabe vode. Izvedena sta bila dva poljska poskusa v rastnih sezonah 2013/14 in 2014/15. Vsak poskus je obsegal štiri sosledja poljščin v kolobarju in sicer : 1 - koruza nato pšenica  (CS1); 2 - koruza, kratkosezonska detelja (SSC), potem pšenica (CS2); 3 -  čičerka, SSC,  potem pšenica (CS3); 4 - čičerka v medsetvi s koruzo, SSC, potem pšenica (CS4). Najmanjša količina dodane vode je bila v sistemu CS1, kar je rezultiralo v majhnem pridelku pšenice in koruze in najmanjši učinkovitosti izrabe vode. Največ vode je bilo dodano v kolobarjih CS2 in CS4 (enake količine). Največji pridelek in največja učinkovitost izrabe vode sta bila dosežena v kolobarju CS3. Največji pridelek koruze in največja učinkovitost izrabe vode sta bila dosežena v kolobarju CS4. Največja celokupna produktivnost (170.88 in 213.43 CU ha^-1 v prvi in drugi rastni sezoni)  in največja  učinkovitost izrabe vode (0.093 in 0.114 CU m^-3 v prvi in drugi rastni sezoni) sta bili za preučevane kolobarje deseženi v kolobarju CS3. Zaključimo lahko, da je večja učinkovitost izrabe vode za pšenico na peščenih tleh dosežena v kolobarju z dvema metuljnicama pred njo (CS3) in za koruzo z medsetvijo metuljnice (CS4).

koruza; pšenica; kratkosezonska detelja; čičerka; medsetev čičerke v koruzo; žitne enote; Assiut upravna enota

Abou-Keriasha M.A., Eisa N. M.A. and Lamlom M.M. (2013). Benefits of legume crops in rotation and intercropping for increased production and land use. Egyptian Journal of Agronomy, 35(2), 183-197.

Allen R.G., Jensen M.E., Wright J.L. and Burman R.D, (1989). Operational estimate of reference evapotranspiration. Agronomy Journal, 81, 650-662. doi:10.2134/agronj1989.00021962008100040019x

Andersen M.K., (2005). Competition and complementarily in annual intercrops: the role of plant available nutrients. PhD thesis, Department of Soil Science, Royal Veterinary and Agricultural University, Copenhagen, Denmark.

Bado B.V., Bationo A., and Cescas M.P., (2006). Assessment of cowpea and groundnut contributions to soil fertility and succeeding sorghum yields in the Guinean savannah zone of Burkina Faso (West Africa). Biology and Fertility of Soils, 43, 171-176. doi:10.1007/s00374-006-0076-7

Banik P.,Midya A., Sarkar B. K. and 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. doi:10.1016/j.eja.2005.10.010

Brankatschk G. and Finkbeiner M. 2014. Application of the Cereal Unit in a new allocation procedure for agricultural life cycle assessments. Journal of Cleaner Production, 73, 72–79. doi:10.1016/j.jclepro.2014.02.005

Brockhaus, J. 1962. ABC der Landwirtschaft, Band (i). A-K p. 488-489. VEB, Brock HausVerlag, Leipzig.

Dhar P.C., Awal M.A., Sultan M.S., Rana M.M., Sarker A., 2013.Interspecific competition, growth and productivity of maize and pea in intercropping mixture. Journal of Crop Science, 2(10), 136-143.

Eskandari H., Ghanbari A., and Javanmard A. 2009. Intercropping of cereals and legumes for forage production. Notulae Scientia Biologicae, 1(1), 7 – 13.

Espinoza S., Ovalle C., Zagal E., Matus I., Pozo A., 2015. Contribution of legumes to the availability of soil nitrogen and its uptake by wheat in Mediterranean environments of central Chile. Chilean Journal of Agricultural Research, 75(1), 111-121.

doi:10.4067/S0718-58392015000100016

FAO. 2003. Unlocking the water potential of agriculture. FAO Corporate Document Repository. Rome, FAO.

Ferguson B.J., Lin M.H., Gresshoff P.M, 2013. Regulation of legume nodulation by acidic growth conditions. Plant Signal Behavior, 8(3), e23426. doi:10.4161/psb.23426

Ghanbari A., M. Dahmardeh, B. A. Siahsar and M. Ramroudi. 2010. Effect of maize (Zea mays L.) - cowpea (Vigna unguiculata L.) intercropping on light distribution, soil temperature and soil moisture in arid environment. Journal of Food, Agriculture and Environment, 8(1):102-108.

Gomez K.A., and Gomez A.A., 1984. Statistical procedures for agriculture research 2nd Edition. John Wiley and Sons. New York, pp. 317-333.

Hakim M.A., Hossain A., Teixeira da Silva J.A., Zvolinsky V.P., Khan M.M. 2012. Yield, protein and starch content of 20 wheat (Triticum aestivum L.) genotypes exposed to high temperature under late sowing conditions. Journal of Science Research, 4(2):477–489. doi:10.3329/jsr.v4i2.8679

Hamd-Alla W.A., Shalaby E.M., Dawood R.A., and Zohry A.A., 2015. Effect of crop sequence and nitrogen fertilization on productivity of wheat. Elixir International Journal of Agriculture, 88, 36215-36222.

Hassan H.M., Marschner P., McNeill A., 2010. Growth, P uptake in grain legumes and changes in soil P pools in the rhizosphere. 19th World Congress of Soil Science, Soil Solutions for a Changing World, 1 – 6 August 2010, Brisbane, Australia.

Jackson M.L., 1958. Soil Chemical Analysis. Prentice Hall. Englewood Cliffs. New Jersey. USA.

Kamel, A.S., El-Masry M.E. and Khalil H.E., 2010. Productive sustainable rice based rotations in saline-sodic soils in Egypt. Egyptian Journal of Agronomy, 32(1):73-88.

Kamel A.S., Zohry A.A.and Ouda, S., 2016. Unconventional Solution to Increase Crop Production under Water Scarcity. In: Major Crops and Water Scarcity in Egypt. Springer Publishing House. pp 99-114.

Kariaga, B.M. 2004, Intercropping maize with cowpeas and beans for soil and water management in western Kenya. 13th International Soil Conservation Organization Conference – Brisbane, July 2004. Paper No. 993.

Kirkegaard J., Christen O., Krupinsky J., Layzell D., 2008. Review: Break crop benefits in temperate wheat production. Field Crops Research, 107, 185-195. doi:10.1016/j.fcr.2008.02.010

Kumpawat, B.S. and Rathore, S.S., 2003. Effect of preceding grain legumes on growths, yield, nutrient content and uptake by wheat under different nitrogen levels. Field Crops Research, 25(2), 209-214.

Kwari J.D., 2005. Soil fertility status in some communities of southern Borno. Final report to PROSAB Project, Maiduguri, Nigeria. p. 21.

Macák M., Žák S., Andrejčíková M. 2015. Productivity and macro elements content of cereal and legume crops. Acta fytotechn zootechn, 18, 160-162.

McCallum M.H., Kirkegaard J.A., Green T., Cresswell H.P., Davies S.L., and Angus J.F., 2004. Improved subsoil macro-porosity following perennial pastures. Australian Journal of Experimental Agriculture, 44, 299-307. doi:10.1071/EA03076

Megawer E.A, Sharaan A.N., and El-Sherif A.M., 2010.Effect of intercropping patterns on yield and its components of barley, lupine or chickpea grown in newly reclaimed soil. Egyptian Journal of Applied Science, 25(9), 437-452.

Najibnia, S., Koocheki, A., N. Mahallati , and M. Porsa. 2014. Water capture efficiency, use efficiency and productivity in sole cropping and intercropping of rapeseed, bean and corn. European Journal of Sustainable Development. 3(4): 347-358. doi:10.14207/ejsd.2014.v3n4p347

Nofal, N., 2012. Effect of intercropping faba bean on sugar beet under different nitrogen fertilization. MSc thesis, El-Minia University. Egypt.

Osborne C.A., Peoples M.B., and Janssen P.H., 2010. Detection of a reproducible, single-member shift in soil bacterial communities exposed to low levels of hydrogen. Applied Environmental Microbiology, 76, 1471-1479. doi:10.1128/AEM.02072-09

Rochester, I.J., M.B. Peoples, N.R. Hulugalle, R.R. Gault, and G.A. Constable, 2001. Using legumes to enhance nitrogen fertility and improve soil conditions in cotton cropping systems. Field Crops Research, 70, 27-41. doi:10.1016/S0378-4290(00)00151-9

Porter, J. R., M. Gawith. 1999. Temperatures and the growth and development of wheat: a review. European Journal of Agronomy, 10:23–36. doi:10.1016/S1161-0301(98)00047-1

Sheha A.M., Nagwa R. Ahmed and A.M. Abou-Elela. 2014. Effect of crop sequence and nitrogen levels on rice productivity. Annals of Agricultural Science, 52 (4): 451 – 460.

Singh, N.B., Singh, P.P., and Nair, K.P., 1986. Effect of legume intercropping on enrichment of soil nitrogen, bacterial activity and productivity of associated maize crops. Experimental Agriculture, 22, 339-344. doi:10.1017/S0014479700014587

Snyder R.L., Orang M., Bali K. and Eching S., 2004. Basic irrigation scheduling BIS. http://www.waterplan.water.ca.gov/landwateruse/wateruse/Ag/CUP/Californi/Climate_Data_010804.xls.

Valipour M. 2012a. HYDRO-MODULE determination for Vanaei village in Eslam Abad Gharb, Iran. ARPN Journal of Agricultural and Biological Science, 7(12):968-976.

Valipour, M. 2012b. Ability of Box-Jenkins Models to Estimate of Reference Potential Evapotranspiration (A Case Study: Mehrabad Synoptic Station,

Tehran, Iran). IOSR Journal of Agriculture and Veterinary Science, 1(5):

-11. doi:10.9790/2380-0150111

Valipour, M. 2014. Analysis of potential evapotranspiration using limited weather data. Applied Water Science. doi:10.1007/s13201-014-0234-2. doi:10.1007/s13201-014-0234-2

Valipour M. 2016. Variations of land use and irrigation for next decades under different scenarios. Irriga, Botucatu, Edição Especial, Irrigação, p. 262-288.

Zhao, J., Xu, Z., Zuo, D. and Wang, X. 2015. Temporal variations of reference evapotranspiration and its sensitivity to meteorological factors in Heihe River Basin, China. Water Science and Engineering, 8(1): 1-8. doi:10.1016/j.wse.2015.01.004

Zohry A.A., 2005a. Effect of preceding winter crops and intercropping on yield, yield components and associated weeds in maize. Annals of Agricultural Science,43(1), 139-148.

Zohry, A.A., 2005b. Effect of relaying cotton on some crops under bio-mineral N fertilization rates on yield and yield components. Annals of Agricultural Science,43(1), 89-103.

Yan F., Schubert S., Mengel K., 1996. Soil pH changes during legume growth and application of plant material. Biology and Fertility of Soils, 23(3), 236-242. doi:/10.1007/BF00335950