Your search found 134 records
1 Zavaleta, L. R.; Lacewell, R. D.; Taylor, R. C. 1980. Open-loop stochastic control of grain sorghum irrigation levels and timing. Reprinted from American Journal of Agricultural Economics. 62(4):785-792.
(Location: IWMI-HQ Call no: P 1997 Record No: H08704)
2 Kluitenberg, G. J.; Biggar, J. W. 1992. Canopy temperature as a measure of salinity stress on sorghum. Irrigation Science, 13(3):115-121.
(Location: IWMI-HQ Call no: PER Record No: H011458)
3 Sweeney, D. W.; Lamm, F. R. 1993. Timing of limited irrigation and N-injection for grain sorghum. Irrigation Science, 14(1):35-39.
(Location: IWMI-HQ Call no: PER Record No: H013421)
4 Fipps, G.; New, L. 1993. Efficient grain sorghum irrigation on the Texas high plains. Irrigation Journal, 43(5):30-31.
(Location: IWMI-HQ Call no: PER Record No: H013437)
5 El-Haddad, E. S. H. M.; O'Leary, J. W. 1994. Effect of salinity and K/Na ratio of irrigation water on growth and solute content of Atriplex amnicola and Sorghum bicolor. Irrigation Science, 14(3):127-133.
(Location: IWMI-HQ Call no: PER Record No: H013987)
6 Girdhar, I. K.; Singh, N. T.; Prasad, R. 1991. Avoid rice-based cropping system if irrigation water is sodic. Indian Farming, 41(9):17-18.
Sodic soils ; Water quality ; Groundwater ; Irrigation requirements ; Water requirements ; Crop yield ; Cropping systems ; Rice ; Wheat ; Sorghum ; Farmer participation / India / Haryana
(Location: IWMI-HQ Call no: P 3586 Record No: H015178)
7 Kim, C. S.; Moore, M. R.; Hanchar, J. J.; Nieswiadomy, M. 1989. A dynamic model of adaptation to resource depletion: Theory and an application to groundwater mining. Journal of Environmental Economics and Management, 17(1):66-82.
Groundwater extraction ; Mathematical models ; Aquifers ; Common property ; Crop production ; Cotton ; Sorghum ; Water allocation / USA / Texas
(Location: IWMI-HQ Call no: P 3606 Record No: H015293)
8 Shih, C. C. C. 1993. Study on optimal irrigation water requirement of sorghum. In ICID, 15th International Congress on Irrigation and Drainage, The Hague, Netherlands, 1993: Water management in the next century: Transactions: Vol.1-C, Question 44, R73-R103: Planning and design of irrigation and drainage systems. New Delhi, India: ICID. pp.1167-1177.
Water requirements ; Drip irrigation ; Sorghum ; Irrigation requirements ; Soil moisture ; Evapotranspiration ; Water balance ; Models ; Field tests ; Lysimetry / Taiwan
(Location: IWMI-HQ Call no: ICID 631.7 G000 ICI Record No: H015347)
9 Mohan, S.; Arumugam, N. 1994. Crop coefficients of major crops in South India. Agricultural Water Management, 26(1/2):67-80.
Water requirements ; Irrigation requirements ; Evapotranspiration ; Regression analysis ; Cotton ; Sorghum ; Millets ; Models / India / Tamil Nadu / Karnataka
(Location: IWMI-HQ Call no: PER Record No: H015480)
10 Baez-Gonzalez, A. D.; Jones, J. G. W. 1995. Models of sorghum and pearl millet to predict forage dry matter production in semi-arid Mexico: 1. Simulation models. Agricultural Systems, 47(2):133-145.
(Location: IWMI-HQ Call no: PER Record No: H015868)
11 Baez-Gonzalez, A. D.; Jones, J. G. W. 1995. Models of sorghum and pearl millet to predict forage dry matter production in semi-arid Mexico: 2. Regression models. Agricultural Systems, 47(2):147-159.
(Location: IWMI-HQ Call no: PER Record No: H015869)
12 Bryant, K. J.; Lacewell, R. D.; Mjelde, J. W.; Benson, V. W.; Williams, J. R. 1993. Using soil water, crop response, and economic information to manage irrigation water. In Heatwole, C. D. (Ed.), Application of advanced information technologies: Effective management of natural resources: Proceedings of the 18-19 June 1993 Conference, Spokane, Washington: St. Joseph, MI, USA: ASAE. pp.179-187.
Soil-water-plant relationships ; Simulation models ; Irrigation management ; Irrigation scheduling ; Decision support tools ; Soil moisture ; Maize ; Sorghum / USA / Texas
(Location: IWMI-HQ Call no: 004 G000 HEA Record No: H015914)
13 Hassanein, A. H. M.; Azab, A. M. 1993. Salt tolerance of grain sorghum. In Lieth, H.; Al Masoom, A. A. (Eds.), Towards the rational use of high salinity tolerant plants: Vol.2 - Agriculture and forestry under marginal soil water conditions. Proceedings of the first ASWAS conference, United Arab Emirates University, Al Ain, UAE, 8-15 December 1990. Dordrecht, Netherlands: Kluwer Academic Publishers. pp.153-156.
(Location: IWMI-HQ Call no: 631.7.5 G000 LEI Record No: H015928)
14 Patil, S. N.; Khakare, M. S.; Raut, R. S. 1994. Effect of in-situ moisture conservation measures on yield, water consumption, evapotranspiration and water use efficiency of grain sorghum under rainfed condition. PKV Research Journal, 18(2):170-172.
(Location: IWMI-HQ Call no: P 3676 Record No: H016064)
15 Drinkwater, M. 1994. Knowledge, consciousness and prejudice: Adaptive agricultural research in Zambia. In Scoones, I.; Thompson, J. (Eds.), Beyond farmer first: Rural people's knowledge, agricultural research and extension practice. London, UK: Intermediate Technology Publications. pp.32-41.
(Location: IWMI-HQ Call no: 630.72 G000 SCO Record No: H016208)
16 Francois, L. E.; Donovan, T.; Mass, E. V. 1984. Salinity effects on seed yield, growth, and germination of grain sorghum. Agronomy Journal, 76:741-744.
(Location: IWMI-HQ Call no: P 3836 Record No: H016611)
17 Jones, C. W. 1983. The impact of the SEMRY I Irrigated Rice Production Project on the organization of production and consumption at the intrahousehold level. Report prepared for AID, Bureau for Program and Policy Coordination. Nutrition and Development Project paper no.83-1. 139p.
Agricultural economics ; Rice ; Sorghum ; Crop production ; Households ; Female labor ; Women / Cameroon
(Location: IWMI-HQ Call no: P 3900 Record No: H016916)
18 Carsky, R. J.; Ndikawa, R.; Singh, L.; Rao, M. R. 1995. Response of dry season sorghum to supplemental irrigation and fertilizer N and P on vertisols in northern Cameroon. Agricultural Water Management, 28(1):1-8.
(Location: IWMI-HQ Call no: PER Record No: H03518)
A series of trials were conducted to quantify response of dry season transplanted sorghum to water and fertilizer application in order to test the hypothesis that soil moisture limits production more than nutrient supply. The trials were conducted at two field sites representative of a large land area in the Lake Chad Basin of Africa. Water was clearly the limiting factor as grain yield response to two irrigations (10 cm total) was a statistically significant 58% over 3 years. One irrigation during vegetative growth resulted in sorghum grain yield increases of 24-29%. Response to P fertilizer was negligible. Response to N fertilizer was 32% over three environments but was not statistically significant at P<0.05. Future research should focus on improvements in soil moisture availability, either through increased soil moisture storage or through reduced evaporative losses.
19 Mastrorilli, M.; Katerji, N.; Rana, G. 1995. Water efficiency and stress on grain sorghum at different reproductive stages. Agricultural Water Management, 28(1):23-34.
(Location: IWMI-HQ Call no: PER Record No: H01992)
20 Hussain, Z.; El-Kady, M. 1995. The supply response of major crops and crop substitutability in Egypt. Paper, National Water Research Center (Egypt), Strategic Research Program. 15p. (Working paper series no.15-4)
Water resource management ; Agricultural research ; Crop production ; Maize ; Rice ; Wheat ; Cotton ; Sugarcane ; Sorghum ; Research methods ; Agricultural prices ; Models / Egypt
(Location: IWMI-HQ Call no: P 4061 Record No: H017468)
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