241. Crops for the future in Papua New Guinea.

• Authors:
  • Nevenimo, T.
  • Quartermain, A.
  • Kurika, L.
  • Moxon, J.
• Source: Science in New Guinea Journal
• Volume: 30
• Year: 2010
• Summary: Papua New Guinea has over 200 crop species that are being utilized, but information in terms of quantity and quality is extremely variable and sparse for most of these crops. The crop species of interest as crops for the future are determined by growing conditions in agro-ecological zones but about 11 indigenous and 25 exotic species of fruits, nuts and vegetables have been identified. Future research needs to include evaluation of these crops for biodiscovery or biofuels, identification of those that are high yielding and of high nutritive value for food, assessment of those meeting domestic or export demand, pest and disease tolerance or resistance and suitability for crop rotations or intercropping. Post-harvest factors are also seen as important in the development of underutilized crops. The priority species include the major staples (aroids and sweet potato), galip nut ( Canarium indicum), noni ( Morinda citrifolia), okari ( Terminalia kaernbacchii), sago ( Metroxylon sagu), aibika ( Abelmoschus manihot), aupa ( Amaranthus spp.), pitpit ( Sacchurum edule), pandanus ( Pandanus spp.) and kava ( Piper methysticum). Galip nut is highlighted as an excellent example of where progress has been made in development for commercialization. Many factors are important for success but public-private partnerships are possibly one of the major factors.

242. Potential of Leguminous Cover Crops in Management of a Mixed Population of Root-knot Nematodes (Meloidogyne spp.)

• Authors:
  • Brandenburg, R. L.
  • Pembroke, B.
  • Gowen, S. R.
  • Osei, K.
  • Jordan, D. L.
• Source: Journal of Nematology
• Volume: 42
• Issue: 3
• Year: 2010
• Summary: Root-knot nematode is an important pest in agricultural production worldwide. Crop rotation is the only management strategy in some production systems, especially for resource poor farmers in developing countries. A series of experiments was conducted in the laboratory with several leguminous cover crops to investigate their potential for managing a mixture of root-knot nematodes (Meloidogyne arenaria M. incognita, M. javanica). The root-knot nematode mixture failed to multiply on Mucuna pruriens and Crotalaria spectabilis but on Dolichos lablab the population increased more than 2-fold when inoculated with 500 and 1,000 nematodes per plant. There was no root-galling on M. pruriens and C. spectabilis but the gall rating was noted on D. lablab. Greater mortality of juvenile root-knot nematodes occurred when exposed to eluants of roots and leaves of leguminous crops than those of tomato; 48.7% of juveniles died after 72 It exposure to root eluant of C. spectabilis. The leaf eluant of D. lablab was toxic to nematodes but the root eluant was not. Thus, different parts of a botanical contain different active ingredients or different concentrations of the same active ingredient. The numbers of root-knot nematode eggs that hatched in root exudates of M. pruriens and C. spectabilis were significantly lower (20% and 26%) than in distilled water, tomato and P vulgaris root exudates (83%, 72% and 89%) respectively. Tomato lacks nematotoxic compounds found in M. pruriens and C. spectabilis. Three months after inoculating plants with 1,000 root-knot nematode juveniles the populations in pots with M. prurient, C. spectabilis and C. retusa had been reduced by approximately 79%, 85% and 86% respectively; compared with an increase of 262% nematodes in pots with Phaseolus vulgaris. There was significant reduction of 90% nematodes in fallow pots with no growing plant. The results from this study demonstrate that some leguminous species contain compounds that either kill root-knot nematodes or interfere with hatching and affect their capacity to invade and develop within their roots. M. pruriens, C. spectabilis and C. retusa could be used with effect to decrease a mixed field populations of root-knot nematodes.

243. Extent of adoption of improved practices of mango production by mango growers in Muzaffarnagar district of Uttar Pradesh.

• Authors:
  • Singh, G. P.
  • Singh, K. V.
  • Priyadarshi, A.
• Source: INDIAN RESEARCH JOURNAL OF EXTENSION EDUCATION
• Volume: 10
• Issue: 3
• Year: 2010
• Summary: A study conducted among mango fruit growers revealed that nearly sixty per cent of fruit growers had moderate extent of adoption of mango production technology. With respect to extent of adoption of fruit growers on various components of improved mango production technology, majority of them had fully adopted land preparation, method of propagation, time, method and distance of planting, planting density, irrigation time, training and pruning, and harvesting method. Majority of farmers had partial adoption of such practices as adoption of high yielding variety, selecting good nursery, interculture practices, harvesting, packing and handling. However, majority of farmers did not adopt such practices as summer ploughing, application of manure and fertilizers (dose, time and method), intercrops, plant growth regulators, green manuring, insect pests and diseases, physiological disorders, and marketing procedures. Among the correlates of extent of adoption of mango production technology, religion, land size, education, farm power, socio-economic status, risk taking behaviour, innovativeness, economic aspiration, scientific orientation and credit orientation were positively and significantly associated with fruit grower's extent of adoption of improved mango production technology at 0.01 level of probability. Regression analysis of extent of adoption of fruit growers on improved mango production technology revealed that level of knowledge of mango cultivation practices was found to be contributing positively and significantly in predicting the extent of adoption of mango fruit growers.

244. Vineyard Weed Seedbank Composition Responds to Glyphosate and Cultivation after Three Years

• Authors:
  • Belina, K.
  • Baumgartner, K.
  • Steenwerth, K.
  • Veilleux, L.
• Source: Weed Science
• Volume: 58
• Issue: 3
• Year: 2010
• Summary: This research compared effects of the weed control practice, soil cultivation, and the conventional practice, glyphosate application on weed seedbank, in a vineyard system. The experiment was conducted in a commercial wine-grape vineyard in the Napa Valley of northern California from 2003 to 2005. The annual treatments were "winter-spring glyphosate," "spring cultivation," "fall-spring cultivation," and "fall cultivation-spring glyphosate," and were applied "in-row," under the vine. Composition of the weed seedbank collected in 2002 before treatment establishment did not differ among treatments. After 3 yr of weed treatments, detrended correspondence analysis indicated that the composition of spring cultivation and winter-spring glyphosate tended to differ from each other, but the remaining two treatments showed little differentiation. As determined by linear discriminant analysis, the specific weed species were associated with seedbanks of certain treatments. These were Carolina geranium, annual bluegrass, brome grasses, California burclover, and scarlet pimpernel, which do not pose problems with regard to physical aspects of grape production. Although 'Zorro' rattail fescue was ubiquitous among treatments, its distribution between depths in the cultivated treatments indicated that tillage provided some homogenization of seedbank along the vertical soil profile. The seedlings from the seedbank study were not congruent with those measured aboveground in the field, suggesting that both treatment and microclimatic effects in the field may have influenced germination, and thus, aboveground composition.

245. Conservation of natural enemies (Insecta) in the organic tomato crop.; Conservacao de inimigos naturais (Insecta) em tomateiro organico.

• Authors:
  • Pires, C. S. S.
  • Medeiros, M. A. de
  • Gravina, C. S.
  • Langer, L. F.
  • Cavalcante, K. R.
  • Togni, P. H. B.
  • Fontes, E. M. G.
  • Sujii, E. R.
• Source: Arquivos do Instituto Biologico Sao Paulo
• Volume: 77
• Issue: 4
• Year: 2010
• Summary: The adoption of cultural practices such as companion plants and the kind of irrigation system can benefit the community of natural enemies in the agroecosystem due to the increase of more favorable microhabitats available and as a source of alternative resources, mainly in periods of low precipitation. This study evaluated how the tomato+coriander intercrop and the kind of irrigation (drip and sprinkler) could benefit the community of natural enemies in the tomato agroecosystem. This work was carried out in the experimental field of Embrapa Hortalicas, Gama, DF, from September to November 2008. The tomatoes were planted in monoculture or with coriander (companion plant) and irrigated by drip and sprinkler irrigation (three replicates per treatment), forming two groups of experimental plots according to the kind of irrigation. The community of natural enemies was sampled by the direct observation of specimens on 20 tomatoes plants per plot and in the treatments. Coriander plants were shaken over a plastic tray for collection of insects. The abundance, richness and diversity of natural enemies were higher in tomato+coriander plots, regardless of the irrigation system. We observed more species of natural enemies in tomato monoculture plots when it was irrigated by sprinkler irrigation. However, the cultural practices adopted had a different effect on each species or group of species. Therefore, in periods of low precipitation, the tomato+coriander consortium associated with sprinkler irrigation can enhance the conservation of natural enemies in the organic tomato agroecosystem.

246. Greenhouse gas emissions and energy use in UK-grown short-day strawberry (Fragaria xananassa Duch) crops

• Authors:
  • Tzilivakis, J.
  • Osborne, N.
  • Hipps, N.
  • Davies, M.
  • Warner, D. J.
  • Lewis, K. A.
• Source: The Journal of Agricultural Science
• Volume: 148
• Issue: 6
• Year: 2010
• Summary: Reducing greenhouse gas emissions and optimizing energy consumption are important for mitigating climate change and improving resource use efficiency. Strawberry (Fragaria xananassa Duch) crops are a key component of the UK soft fruit sector and potentially resource-intensive crops. This is the first study to undertake a detailed environmental impact assessment of all methods of UK strawberry production. A total of 14 systems with six additional sub-systems grown for between 1 and 3 years were identified. They were defined by the growing of short-day (Junebearer) or everbearer varieties, organic production, covering with polytunnels or grown in the open, soil-grown (with or without fumigation) or container-grown (with peat or coir substrate) and summer or spring planted. Preharvest, the global warming potential varied between 1.5 and 10.3 t CO(2) equiv/ha/crop or 0.13 and 1.14 t CO(2) equiv/t of class 1 fruit. Key factors included the use of tunnels, mulch and irrigation, sterilization of soil with fumigants and the use of peat substrate. Seasonal crops without covers grown where rotation of sufficient length reduced Verticillium (system 4) were the most efficient. System 4a (that did not use mulch) emitted 0.13 t CO(2) equiv/t of class 1 fruit. A second or third cropping year in soil-grown systems prolonged the effect of mulch and soil fumigants. Greenhouse gases from system 4 (with mulch) averaged 0.30 t CO(2) equiv/t of class 1 fruit after 3 years of cropping compared to 0.63 and 0.36 t CO(2) equiv/t after 1 and 2 years, respectively.

247. WaLIS - a simple model to simulate water partitioning in a crop association: the example of an intercropped vineyard.

• Authors:
  • Gary, C.
  • Ripoche, A.
  • Celette, F.
• Source: Agricultural Water Management
• Volume: 97
• Issue: 11
• Year: 2010
• Summary: The introduction of cover crops in vineyards is being tested as it mitigates some undesirable environmental impacts of these cropping systems, such as surface runoff and soil erosion. In some cases, it could even reduce an excessive vegetative vigour of grapevine. However, most of time, wine growers are worried that severe competition for soil resources between the intercrop and grapevines could impair grape yield and quality. WaLIS (Water baLance for Intercropped Systems), a simple model simulating the water resource partitioning in such an association was designed to evaluate and optimize the water regime in intercropped systems. The model is presented and evaluated in this paper in three situations: the same grapevine cultivar (cv. Aranel) with either bare soil, or a temporary intercrop (barley) or a permanent intercrop (tall fescue). All three situations are located in the south of France. It is based on an existing model, designed to simulate the water regime of a bare soil vineyard, which was adapted to take into account the specific features of intercropped systems. Hence it includes a two-compartment representation of the soil particularly adapted to row crops. The simulation of a grass cover growth and its transpiration were added. Finally, particular importance was dedicated to the simulation of surface runoff which was the main source of the original model deviation during the winter period and made difficult multi-year simulations. Now, the model appears to be able to evaluate perennial cropping systems and provide decision support. The WaLIS model simulated the water available for both grapevine and intercrop well, and it proved to be efficient in most of the tested situations and years. The modelling of the water stress experienced by both crops was also generally good and all water fluxes simulated by the model were realistic. The main observed deviation in the simulation of the water soil content occurred during winter, i.e. outside the grapevine growth period. It was very likely due to the use of a constant parameter value for the surface runoff which did not take into account of changes in the soil surface and their effects on water infiltration. Finally, the analysis of sensitivity made on the WaLIS model showed that it is robust and sensitive to a few parameters, which drive the maximal grapevine transpiration and soil evaporation or are linked to the surface runoff simulation. The work also revealed how a good estimate of the total soil water available for each crop is crucial. This model, easy to use and parameterise, can provide sound management advice for designing valuable intercropped cropping systems.

248. Soil Management in the Breede River Valley Wine Grape Region, South Africa. 1. Cover Crop Performance and Weed Control

• Authors:
  • Fourie, J. C.
• Source: South African Journal of Enology and Viticulture
• Volume: 31
• Issue: 1
• Year: 2010
• Summary: Eight cover crop treatments were applied for 12 consecutive years on a medium-textured soil in a vineyard near Robertson (33 degrees 50'S, 19 degrees 54'E). A treatment with full surface straw mulch and full surface post-emergence chemical control applied from just before grapevine bud break to harvest (BB), and one with no cover crop combined with BB, were also applied. The control consisted of mechanical control in the work row and post-emergence chemical control in the vine row applied from bud break to harvest. Rotating Triticale v. Usgen 18 (triticale) and Vicia dasycarpa Ten. (vetch) did not improve the dry matter production (DMP) of either species. Average DMP decreased as follows: triticale > Secale cereale L. v. Henog (rye)/Vicia faba L. v. Fiord (faba bean) mixture > triticale/vetch biennial rotation > triticale/vetch annual rotation > vetch. Triticale (BB) resulted in total winter weed suppression from 1995 to 1996 and from 2001 to 2004. Total weed control from bud break to the pea size berry stage of the grapevines was achieved with straw mulch (BB), triticale (BB), rye/faba bean mixture (BB) and triticale/vetch rotated biennially (BB) from 2001 to 2003. For triticale combined with full surface post-emergence chemical control applied from grapevine berry set (AB), and for triticale/vetch rotated annually (BB), this was restricted to 2001 and 2003. From the pea size berry stage to harvest, straw mulch (BB), triticale (BB), vetch (BB), rye/faba bean mixture (BB) and triticale (AB) reduced the weed stand significantly in comparison to the control.

249. 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

250. 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.