In Irapuato, Guanajuato, Mexico, strawberry crops represent an important source of jobs for many people, particularly women. Traditionally, the crop is fertilized with high a rate of N (350-500 kg N ha(-1)). Thus, the objectives in this study were 1) to quantify the nitrogen uptake derived from fertilizer by the crop through the 15N isotopic technique, and 2) to quantity the water productivity. A strawberry crop cv. Chandler was transplanted to the field and fertilized with 300 kg N ha(-1) as ammonium sulphate 1% 15N atoms excess. The fertilization was split in three applications of 100 kg N ha(-1) at 30, 91 and 157 days after transplanting (dat). The lowest N-efficiency occurred in the period 0-64 dat (7%). The berries always showed the lowest N-efficiency (< 1%). The N-efficiency occurred in stage 64-91 dat. The highest N uptake from fertilizer occurred during the periods 64-91, 128-157, and 188-219 dat. In relation to water, the results indicate "poor" water productivity. The highest value observed occurred between 157-188 dat and is directly related to peak biomass accumulation. The calculated value of water productivity is 1.6 m3 kg(-1) fruit. Our data illustrate the need to continue with studies focused on the optimization the N-fertilizer and water.

The effect of three irrigation calendars: 0-46, 0-40-70, and 0-40-70-90 days after sowing (das) and three N fertilization rates: 120, 180, and 240 kg ha(-1) applied at sowing were studied using 15N and neutron probe on barley (Hordeum vulgare L.). A split plot design with four replicates was used. The results showed that the efficiency use of N-fertilizer in the different irrigation calendars under study was similar (< 22%). The highest proportion of nitrogen derived from fertilizer was low (< 40%) and occurred between 52 to 66 das. Interestingly, eliminating irrigation during flowering stage resulted in an increase in N absorption from fertilizer. In conclusion, a management of these inputs, two irrigation periods and 180 kg N ha(-1) resulted in better management in barley production system.

During the rainy season of 1998, a field experiment was established in Cocula, Guerrero (hot subhumid climate, Awo) and in Montecillo, México (semiarid climate, BS₁), to evaluate the effect of nitrogen (0, 10 and 20 g m⁻²) and environment on phenology, yield and its components, water use efficiency (WUE), and crop evapotranspiration (ETc) and heat units (HU) accumulated during the growth cycle of sunflower (Helianthus annuus L.) cv. Victoria. The crop was planted on June 1 at a density of 7.5 pl m⁻² in both climates. In Cocula, maximum and minimum temperatures were more extreme and rainfall was more intense, while soil was poor in total nitrogen, compared with Montecillo. Crop growth, yield and its components, and water use efficiency were affected significantly by the environment, nitrogen and the interaction environment * nitrogen. The crop cycle in the hot environment was 36 days shorter, with a greater accumulation of HU and ETc. Yield and its components and water use efficiency were significantly higher in Cocula. Nitrogen positively affected the evaluated variables. The interactive effect of environment * nitrogen was observed clearly, since in Cocula there was response to the application of nitrogen in most of the variables evaluated, while in Montecillo there was not.

Algal blooms and fish kills were reported on a river in coastal Georgia (USA) downstream of a poultry-processing plant, prompting officials to conclude the problems resulted from overland flow associated with over-application of wastewater at the plant’s land application system (LAS). An investigation was undertaken to test the hypothesis that contaminated groundwater was also playing a significant role. Weekly samples were collected over a 12-month period along an 18 km reach of the river and key tributaries. Results showed elevated nitrogen concentrations in tributaries draining the plant and a tenfold increase in nitrate in the river between the tributary inputs. Because ammonia concentrations were low in this reach, it was concluded that nitrate was entering via groundwater discharge. Data from detailed river sampling and direct groundwater samples from springs and boreholes were used to isolate the entry point of the contaminant plume. Analysis showed two separate plumes, one associated with the plant’s unlined wastewater lagoon and another with its LAS spray fields. The continuous discharge of contaminated groundwater during summer low-flow conditions was found to have a more profound impact on river-water quality than periodic inputs by overland flow and tributary runoff.