881. Evaluation of Green Covering Potential and Crop Rotation Systems in The Suppression of the Ring Nematode (Mesocriconema xenoplax) in Peach Pre-Planting

• Authors:
  • Radmann, E. B.
  • Casagrande Junior, J. G.
  • Carpena Carvalho, F. L.
  • Gomes, C. B.
• Source: Revista Brasileira de Fruticultura
• Volume: 32
• Issue: 1
• Year: 2010
• Summary: In a field naturally infested with ring nematode (Mesocriconema xenoplax), green covering were tested for their suppressing potential in winter and summer crops comparing to plots kept in fallow lands. Tree crop rotation system with the same plant species tested before (black oat/pig bean/millet/forage radish; forage radish/millet/white oat/corn; and white oat/dwarf velvet bean/wheat/sorghum) were evaluated for suppression potential to nematode M xenoplax for two years, using as control, plots that were kept in fallow lands. The experiments were conducted in the field in a randomized block design with six repetitions. Before and after the establishment of each plot, the nematode populations were evaluated on the number of M xenoplax/100cm3 of soil and the reproduction factor (RF=final population/initial population) of the ring nematode, where RF1,00, favoring of the reproduction. Most of the crops analyzed were unfavorable host (RF

882. Cover crops in processing tomato, snap beans and sweetcorn production yield and harvest quality.

• Authors:
  • Gunter, C. C.
• Source: ISHS Acta Horticulturae IV International Symposium on Ecologically Sound Fertilization Strategies for Field Vegetable Production
• Issue: 852
• Year: 2010
• Summary: Efforts are being made to reduce the negative impacts that high intensity vegetable production can have on the soil. Soil nutrient removal and soil compaction due to heavy equipment can lead to long lasting problems in future production cycles. Producers are beginning to look at the beneficial effects that cover crops can have on soil tilth and fertility. Three rotational cover crop areas were established on the Southwest Purdue Agriculture Center in Vincennes, Indiana and each area was divided into four cover crop plots, no-till wheat, clover, oilseed radish and a bare ground control. Processing tomatoes, sweetcorn and snap beans were planted across the four cover crop plots within each rotational area. Two varieties of each type of vegetable were grown in each cover crop. Processing tomatoes had significantly less yield in the no-till wheat cover crop compared to the other three cover crops. There were also a higher proportion of green and turning fruit in that treatment. Snap beans showed significantly higher yields when grown in the oilseed radish and clover cover crops. Sweetcorn had significantly shorter ear length when grown in the no-till wheat cover crop. Varietal differences exist with cover crops, suggesting that some varieties perform better than others when using a specific cover crop.

883. An estimation of global virtual water flow and sources of water withdrawal for major crops and livestock products using a global hydrological model.

• Authors:
  • Kanae, S.
  • Inuzuka, T.
  • Hanasaki, N.
  • Oki, T.
• Source: Journal of Hydrology
• Volume: 384
• Issue: 3/4
• Year: 2010
• Summary: The concept of virtual water, which is the volume of water consumption required to produce commodities traded to an importing or exporting nation (or any region, company, individual, etc.), is a useful complement to water resource analyses of water availability and use by region. Identifying the source of virtual water, such as precipitation (green water) and irrigation water (blue water), further enhances this concept because each differs in the level of sustainability and opportunity cost. Recent improvements in global hydrological models consisting of both physically based hydrological and anthropogenic activity modules enabled us to simulate the virtual water content of major crops consistent with their global hydrological simulation. Enhancing one of these models, called H08, we were able to assess two major sources of virtual water flow or content simultaneously: green water and blue water. Blue water was further subdivided into three subcategories ( i.e., streamflow, medium-size reservoirs, and nonrenewable and nonlocal blue water). We conducted a global hydrological simulation for 15 years from 1985 to 1999 at a spatial resolution of 0.5degrees * 0.5degrees (longitude and latitude). Total precipitation on land was 113,900 km 3 yr -1, with 72,080 km 3 yr -1 on average evaporating in the period 1985-1999. Green water evapotranspiration from rainfed and irrigated cropland and blue water evapotranspiration from irrigated cropland was estimated at 7820, 1720, and 1530 km 3 yr -1, respectively. Next, using global trade data for 2000 and the simulated virtual water content of major crops, the virtual water flow was estimated globally. Our results indicated that the global virtual water export ( i.e., the volume of water that an exporting nation consumes to produce the commodities that it trades abroad) of five crops (barley, maize, rice, soybean, and wheat) and three livestock products (beef, pork, and chicken) is 545 km 3 yr -1. Of the total virtual water exports, 61 km 3 yr -1 (11%) are blue water ( i.e., irrigation water) and 26 km 3 yr -1 (5%) are nonrenewable and nonlocal blue water.

884. Quantifying blue and green virtual water contents in global crop production as well as potential production losses without irrigation.

• Authors:
  • Döll, P.
  • Siebert, S.
• Source: Journal of Hydrology
• Volume: 384
• Issue: 3-4
• Year: 2010
• Summary: Crop production requires large amounts of green and blue water. We developed the new global crop water model GCWM to compute consumptive water use (evapotranspiration) and virtual water content (evapotranspiration per harvested biomass) of crops at a spatial resolution of 5′ by 5′, distinguishing 26 crop classes, and blue versus green water. GCWM is based on the global land use data set MIRCA2000 that provides monthly growing areas for 26 crop classes under rainfed and irrigated conditions for the period 1998-2002 and represents multi-cropping. By computing daily soil water balances, GCWM determines evapotranspiration of blue and green water for each crop and grid cell. Cell-specific crop production under both rainfed and irrigated conditions is computed by downscaling average crop yields reported for 402 national and sub-national statistical units, relating rainfed and irrigated crop yields reported in census statistics to simulated ratios of actual to potential crop evapotranspiration for rainfed crops. By restricting water use of irrigated crops to green water only, the potential production loss without any irrigation was computed. For the period 1998-2002, the global value of total crop water use was 6685 km 3 yr -1, of which blue water use was 1180 km 3 yr -1, green water use of irrigated crops was 919 km 3 yr -1 and green water use of rainfed crops was 4586 km 3 yr -1. Total crop water use was largest for rice (941 km 3 yr -1), wheat (858 km 3 yr -1) and maize (722 km 3 yr -1). The largest amounts of blue water were used for rice (307 km 3 yr -1) and wheat (208 km 3 yr -1). Blue water use as percentage of total crop water use was highest for date palms (85%), cotton (39%), citrus fruits (33%), rice (33%) and sugar beets (32%), while for cassava, oil palm and cocoa, almost no blue water was used. Average crop yield of irrigated cereals was 442 Mg km -2 while average yield of rainfed cereals was only 266 Mg km -2. Average virtual water content of cereal crops was 1109 m 3 Mg -1 of green water and 291 m 3 Mg -1 of blue water, while average crop water productivity of cereal crops was 714 g m -3. If currently irrigated crops were not irrigated, global production of dates, rice, cotton, citrus and sugar cane would decrease by 60%, 39%, 38%, 32% and 31%, respectively. Forty-three per cent of cereal production was on irrigated land, and without irrigation, cereal production on irrigated land would decrease by 47%, corresponding to a 20% loss of total cereal production. The largest cereal production losses would occur in Northern Africa (66%) and Southern Asia (45%) while losses would be very low for Northern Europe (0.001%), Western Europe (1.2%), Eastern Europe (1.5%) and Middle Africa (1.6%). Uncertainties and limitations are discussed in the manuscript, and a comparison of GCWM results to statistics or results of other studies shows good agreement at the regional scale, but larger differences for specific countries.

885. Plant density and nitrogen studies in Zero tillage maize ( Zea mays L.).

• Authors:
  • Reddy, P. R. R.
  • Veeranna, G.
  • Rao, L. J.
• Source: Journal of Research ANGRAU
• Volume: 38
• Issue: 3/4
• Year: 2010
• Summary: Maize ( Zea mays) is one of the important cereal crops cultivated in India. Its area is expanding fast in Andhra Pradesh. Plant density in corn, varies with soil, rainfall, hybrid, planting pattern and field preparation (Olson and Sander, 1988). Of late, Zero tillage maize, after kharif rice is gaining popularity among the farming community in Andhra Pradesh. In zero tillage, after harvesting kharif rice, maize seeds will be dibbled under optimum moisture condition without any field preparation. Pre emergence spraying of atrazine in combination with paraquat or glyphosate is practiced to control weeds. Fertilizer application starts from 15 days after sowing in various quantities. In general, intercultivation is not practiced. The crop receives 4-6 irrigations depending on soil type.

886. Greenhouse gas mitigation economics for irrigated cropping systems in northeastern Colorado.

• Authors:
  • Halvorson, A. D.
  • Archer, D. W.
• Source: Soil Science Society of America Journal
• Volume: 74
• Issue: 2
• Year: 2010
• Summary: Recent soil and crop management technologies have potential for mitigating greenhouse gas emissions; however, these management strategies must be profitable if they are to be adopted by producers. The economic feasibility of reducing net greenhouse gas emissions in irrigated cropping systems was evaluated for 5 yr on a Fort Collins clay loam soil (a fine-loamy, mixed, superactive, mesic Aridic Haplustalf). Cropping systems included conventional tillage continuous corn ( Zea mays L.) (CT-CC), no-till continuous corn (NT-CC), and no-till corn-bean (NT-CB) including 1 yr soybean [ Glycine max (L.) Merr.] and 1 yr dry bean ( Phaseolus vulgaris L.). The study included six N fertilization rates ranging from 0 to 246 kg ha -1. Results showed highest average net returns for NT-CB, exceeding net returns for NT-CC and CT-CC by US$182 and US$228 ha -1, respectively, at economically optimum N fertilizer rates. Net global warming potential (GWP) generally increased with increasing N fertilizer rate with the exception of NT-CC, where net GWP initially declined and then increased at higher N rates. Combining economic and net GWP measurements showed that producers have an economic incentive to switch from CT-CC to NT-CB, increasing annual average net returns by US$228 ha -1 while reducing annual net GWP by 929 kg CO 2 equivalents ha -1. The greatest GWP reductions (1463 kg CO 2 equivalents ha -1) could be achieved by switching from CT-CC to NT-CC while also increasing net returns, but the presence of a more profitable NT-CB alternative means NT-CC is unlikely to be chosen without additional economic incentives.

887. The influence of the crop rotation on some indicators of the wheat yield quality in the conditions of the Crisurilor plain.

• Authors:
  • Domua, C.
  • Borza, I.
  • Ardelean, I.
  • Domuta, C.
  • Bandici, G.
  • Radu, B.
• Source: Natural Resources and Sustainable Development
• Issue: 2010
• Year: 2010
• Summary: The paper sustain the importance of the crop rotation on quality of the wheat yield and is based on the results carried out during 2003-2006 in a long term trial out placed on the preluvosoil from Oradea in 1990. Both in nonirrigated and irrigated conditions the smallest values of the protein, wet gluten and dry gluten were obtained in wheat monocrop; the values increased in the crop rotation wheat maize and the biggest values were registered in the crop rotation wheat-maize-soybean.

888. Challenges and characteristics of the South American grain and oilseed postharvest system.

• Authors:
  • Bartosik, R.
• Source: Julius-Kühn-Archiv
• Issue: 425
• Year: 2010
• Summary: Concerning grain production, South America is divided in two main regions: (1) the Mercosur region (Argentina, Brazil, Uruguay and Paraguay) which produces more than 250 million tonnes of grains and oilseeds, and (2) the Andes Mountain region countries, which are net importers of these products. The main challenges related to grain postharvest that South America is facing are to minimize the quality and quantity losses; improve the food safety; enhance the capability for segregation and traceability of identity preserved (IP) grains; and incorporate technology to maintain the overall efficiency of the postharvest system. Among the critical points affecting the efficiency of the system are the shortage of permanent storage capacity; large storage structures which affects the segregation of IP grains; deficient transportation system (roads and railroads); poor management of integrated pest control system; and unsatisfied demand of formal and informal education in suitable grain postharvest technologies and practices. However, the region remains highly competitive in producing and delivering food for the rest of the world and it has demonstrated high capacity for incorporating cost efficient grain handling technologies. As a result, one of the main changes in the region was the appearance of the silobag system for temporary storage of dry grain and oilseeds. Each silobag can hold approximately 200 tonnes of wheat and with the available handling equipment is quite simple to load and unload. During the 2008 harvest season, more than 33 million tonnes of grain were stored in these plastic bags in Argentina (including corn, soybean, wheat, sunflower, malting barley, canola, cotton seed, rice, lentils, sorghum, beans and even fertilizers). The silobag technology is also being adopted not only in neighbor countries, but also in countries around the world such as the USA, Mexico, South Africa, Australia, Russia and Ukraine, among others.

889. Analysis of methane yields from energy crops and agricultural by-products and estimation of energy potential from sustainable crop rotation systems in EU-27

• Authors:
  • Friedl, A.
  • Amon, B.
  • Boesch, P.
  • Leonhartsberger, C.
  • Bauer, A.
  • Amon, T.
• Source: Clean Technologies and Environmental Policy
• Volume: 12
• Issue: 2
• Year: 2010
• Summary: Currently an increasing demand for renewable energy can be observed. A part of this demand could be covered by the production of energy from agrarian biomass. Due to the limited availability of arable land, food and feed production are starting to compete for agrarian resources. A way out of this dilemma is to develop concepts that are based on otherwise unused agrarian biomass like straw and include new technologies for the fermentation of lignocellulosic biomass. In this paper, the energy potentials of two different cropping systems are compared. In the energy-based crop rotation system all crops were used either for biogas or ethanol production. In the biorefinery-based approach, the various crops were used in cascades for the production of food as well as feed. Experimental laboratory work and field trials were combined to calculate energy and biomass yields of the crops under investigation. The results demonstrate that steam explosion pretreatment of wheat straw led to a 30% increase in the specific methane yield. The calculated energy output of the biorefinery-based crop rotation system amounted to a total of 126 GJ ha(-1) year(-1). Extrapolating this energy output to the total arable land of the EU-27 member states, 13,608 PJ of energy could be produced. Therefore, biorefinery-based crop rotation systems could provide approximately three times more energy to the European population than energy-based crop rotation systems.

890. Cotton Responses to Tillage and Rotation during the Turn of the Century Drought

• Authors:
  • Frederick, J. R.
  • Fortnum, B. A.
  • Bauer, P. J.
• Source: Agronomy Journal
• Volume: 102
• Issue: 4
• Year: 2010
• Summary: Longer rain-free periods are predicted to occur more often in the southeastern United States as a result of global climate change. This nonirrigated field study was conducted from 1997 through 2002, which coincided with the 1998-2002 drought that affected most of the United States. The objective was to determine the effect of rotation and tillage on cotton (Gossypium hirsutum L.) productivity. Treatments in the study were rotation [cotton rotated with corn (Zea mays L.), cotton planted after a rye (Secale cereale L.) winter cover crop, and continuous cotton with no cover crop] and tillage system (conventional tillage and conservation tillage). Two levels of aldicarb [2-methyl-2-(methylthio)propanal O-{(methylamino)carbonyl}oxime] (0 and 1.18 kg a.i. ha(-1)) were also included because of known soil management effects on thrips (Frankliniella sp.) and root-knot nematodes (Meloidigyne incognita). The predominant soil types were Bonneau loamy sand (loamy, siliceous, subactive, thermic Arenic Paleudult) and Norfolk loamy sand (fine-loamy, kaolinitic, thermic Typic Kandiudult). Rotation did not affect cotton yield in any year. Tillage did not affect cotton yield in 1997. Conservation tillage resulted in an average 25% yield increase in cotton lint yield over conventional tillage during the 5-yr drought. Tillage and aldicarb affected both thrips and root-knot nematodes, but lack of interaction among these factors for lint yield suggested that management of these pests was not the predominant cause for the cotton yield increase with conservation tillage. Conservation tillage for cotton production could be an important method to help mitigate the effects of climate change in the region if change occurs as predicted.