141. Estimating greenhouse gas emissions from soil following liquid manure applications using a unit response curve method

• Authors:
  • Frear, C.
  • Chen, S.
  • Wang, G.
• Source: Geoderma
• Volume: 170
• Year: 2012
• Summary: Quantitative information is critical in policy making related to the roles of agriculture in greenhouse gas (GHG) emissions. A Unit Response (UR) curve method was developed in this study for modeling GHG emissions from soil after liquid manure applications. The emission sources (soils and liquid manures) are conceptualized as a set of linear cascaded chambers with equal storage-release coefficients, or two sets of cascaded chambers in parallel, each set having equal storage-release coefficients. The model is based on a two-parameter gamma distribution. Three parameters in this model denote the number of cascaded chambers, the storage-release coefficient, and the multiplier (referring to the total net emissions) added to the gamma distribution function. These parameters can be expressed as functions of site-specific background fluxes without applications of manure/fertilizer. The method was assessed with emissions data from five fields in Washington State. The results showed that at the WSU and Lynden sites, the average excess CH4 emissions due to manure applications were 0.39 and 0.17 kg CH4-C ha(-1), respectively: the average excess CO2 emissions were 216.50 and 25.20 kg CO2-C ha(-1), respectively; and the average excess N2O were 0.37 and 0.03 kg N2O-N ha(-1), respectively. The UR method may fill the gaps between field measurements, simple emission factor (EF) method, and complex process-oriented models. This method has the potential to be used for estimating additional GHG emissions due to manure/fertilizer applications.

142. Options to reduce N loss from maize in intensive cropping systems in Northern Italy

• Authors:
  • Grignani, C.
  • Sacco, D.
  • Monaco, S.
  • Zavattaro, L.
• Source: Agriculture, Ecosystems & Environment
• Volume: 147
• Year: 2012
• Summary: Maize (Zea mays, L) is not only the main crop in the intensively cultivated Po Plain (Northern Italy), but also the one that produces the largest N Surplus. This study is based on experimental data from the Tetto Frati long-term trial (Turin, NW Italy) to demonstrate that the impact on soil and water quality of high-yielding, maize-based cropping systems can be reduced through proper management. Nitrogen use efficiency and loss indicators were calculated and compared among various management options: (i) maize monoculture at high N fertilizer rates for grain production (most widespread management), (ii) entire plant (with straw) harvest, (iii) double-cropping system with a winter crop, (iv) maize-grass ley rotation, and (v) change in fertilizer type. The entire maize plant removal reduced N leaching by 10-20%; however, carbon sequestration was also reduced. A maize-Italian ryegrass double cropping system improved the efficiency of organic fertilizers, and reduced leaching by 25-40% relative to monoculture. A rotation with grass ley reduced N impact only when fertilized with urea, and not when organic fertilizers were used. Urea, slurry, and farmyard manure were equally utilized by the crop; if distributed and incorporated just before sowing, both organic fertilizers built up the soil organic matter content and reduced N leaching by 20-50% with respect to urea. This study has shown that farmers in NW Italy have several opportunities to continue cultivate maize thus accomplishing agri-environmental legislation.

143. Winter cover crop seeding rate and variety affects during eight years of organic vegetables: II. Cover crop nitrogen accumulation.

• Authors:
  • Brennan, E. B.
  • Boyd, N. S.
• Source: Agronomy Journal
• Volume: 104
• Issue: 3
• Year: 2012
• Summary: Winter cover crops (CC) can improve nutrient use efficiency by scavenging residual soil N. Shoot nitrogen accumulation (NA) of rye ( Secale cereale L.), legume-rye, and mustard was determined in December to February or March during the first 8 yr of the Salinas Organic Cropping Systems (SOCS) trial focused on high-value crops in Salinas, CA. By seed weight, legume-rye included 10% rye, 35% faba bean ( Vicia faba L.), 25% pea ( Pisum sativum L.), 15% common vetch ( V. sativa L.), and 15% purple vetch ( V. benghalensis L.); mustard included 61% Sinapis alba L., and 39% Brassica juncea Czern. Cover crops were fall planted at 1x and 3x seeding rates (SR); 1x SR were 90 (rye), 11 (mustard), and 140 (legume-rye) kg ha -1. Vegetables followed CC annually. Early-season NA was greatest in mustard. Nitrogen accumulation increased more gradually through the season in legume-rye than in other CC. Final NA (kg ha -1) was lower in rye (110) and mustard (114), than legume-rye (151), and varied by year. During December, SR increased NA in legume-rye by 41% but not for the other CC. Legumes contributed 36% of final NA in legume-rye, presumably from N scavenging and biological fixation. Nitrogen accumulation was highly correlated with shoot dry matter of legume-rye but not of rye or mustard. Seed costs per kg of NA were more than two times higher for legume-rye than rye and mustard. We conclude that high SR are necessary to hasten early season NA and minimize N leaching potential in legume-rye mixtures.

144. Soil carbon sequestration in the dryland cropping region of the Pacific Northwest

• Authors:
  • Huggins, D. R.
  • Brown, T. T.
• Source: Journal of Soil and Water Conservation
• Volume: 67
• Issue: 5
• Year: 2012
• Summary: Knowledge of soil organic carbon (SOC) changes that occur under different agricultural practices is important for policy development, carbon (C) marketing, and sustainable land management. Our objective was to quantify agricultural impacts on SOC sequestration for dryland cropping systems in different agroclimatic zones (ACZs) of the Pacific Northwest (PNW). Data from 131 SOC studies were analyzed to assess land management-induced changes in SOC, including the conversion of native ecosystems to agricultural crops, conversion from conventional tillage (CT) to no-tillage (NT), and alternative crop rotations and management practices. Cumulative probabilities of SOC change were developed for assessing uncertainties inherent in SOC studies and for informing SOC markets. These analyses showed that 75% of converted native land lost at least 0.14 to 0.70 Mg C ha(-1) y(-1) (0.06 to 0.31 tn C ac(-1) yr(-1)) over an average of 55 to 74 years depending on ACZ. Converting from CT to NT was predicted to increase SOC at least 0.12 to 0.21 Mg C ha(-1) y(-1) (0.05 to 0.09 tn C ac(-1) yr(-1)) over 10 to 12 years in 75% of studies analyzed and was also ACZ specific. Compared to annual cropping, mixed perennial-annual systems would be expected to gain at least 0.69 Mg C ha(-1) y(-1) (0.31 tn C ac(-1) ha(-1)) over 12 years in 75% of ACZ 2 sites. Other conclusions were that (1) SOC databases are lacking for low precipitation areas of the PNW; such as the dryland wheat-fallow region; (2) baseline sampling of SOC prior to management change is largely nonexistent for PNW databases except for a few notable cases; (3) soil erosion processes have likely impacted SOC and contributed to large variability among studies; (4) sampling methodologies and analyses for SOC have been inconsistent, thereby contributing to SOC variability; and (5) a validated C model for the PNW would aid evaluation of SOC changes due to management, particularly for specific farms and sites with unique SOC history and circumstances.

145. Improving crop production in the arid Mediterranean climate

• Authors:
  • Jensen, C. R.
  • Jacobsen, S. -E
  • Liu, F.
• Source: Field Crops Research
• Volume: 128
• Year: 2012
• Summary: The aim of the present review is to highlight the possibilities of a sustainable crop production in the arid Mediterranean region, which is predicted to suffer from increasingly severe droughts in the future due to climate changes, in addition to increased problems with soil salinity and increased temperatures. Annual rainfall in the region varies between 300 and 1000 mm, covering arid, semi-arid and wet ecosystems. As stress factors often act together, it is important sometimes to focus on multiple stresses affecting the crop, instead of looking at the individual stress separated from the rest. The rainfed farming systems are the most important in the Mediterranean countries. The question is if we can overcome mild to medium level of abiotic stresses by agronomic means. It might be done by using different crops of increased drought and salinity tolerance, and utilizing their stress adaptation mechanisms to optimize crop productivity. However supplemental irrigation used as deficit irrigation has the potential to overcome periods of low rainfall or high temperatures. It is suggested that improvements in crop production may arise from several strategies such as early sowing enabled by minimum tillage, increased use of organic manure, and an efficient weed control. Further, crop rotations will play an important role in improving weed control, minimizing disease risk, and increasing nitrogen availability. Introduction of drought and salt tolerant crop species as quinoa, amaranth and Andean lupin may result in more resilient crop rotations and high value cash crop products. Genotypic increases may arise from selection for early vigour, deep roots, increased transpiration efficiency, improved disease resistance, and high assimilate storage and remobilization. A range of crop and management strategies might be combined for a specific target environment in order to optimize crop productivity. These combinations can then be used as a guidance to future decision support systems for crop production at limited water supply under arid Mediterranean conditions. (C) 2011 Elsevier B.V. All rights reserved.

146. Water and land productivities of wheat and food legumes with deficit supplemental irrigation in a Mediterranean environment.

• Authors:
  • Oweis, T.
  • Karrou, M.
• Source: Agricultural Water Management
• Volume: 107
• Year: 2012
• Summary: Selecting appropriate crops and applying deficit irrigation can help increase water productivity in water-limited regions such as the Mediterranean. The objective of this study was to develop water production functions of major cereal and legume crops under the same environmental and management conditions. Bread and durum wheat, faba bean, chickpea, and lentil were grown under full supplemental irrigation (FSI), two deficit irrigations levels of 2/3 of FSI (2/3SI) and 1/3 of FSI (1/3SI), and under rainfed conditions (no irrigation). In average, the actual evapotranspirations (ETs) under FSI were 549, 552, 365, 451 and 297 mm, for bread wheat, durum wheat, faba bean, chickpea and lentil, respectively. For the same crops, they were 463, 458, 330, 393 and 277 mm for the treatment 2/3SI and 357, 351, 265, 318 and 244 mm for the treatment 1/3SI, respectively. In the case of the rainfed treatment, ETs for the mentioned crops were 250, 251, 227, 237 and 215 mm, respectively. The experiment was conducted at the ICARDA experimental station at Tel Hadya, near Aleppo, Syria, over three growing seasons from 2007 to 2010. Results showed that, in general, the treatment with 1/3 of FSI gave the highest rate of increase in grain yield and water productivity. The mean grain yield from rainfed, 1/3SI, 2/3SI, and FSI were 1.36, 3.82, 5.18, and 5.70 t/ha for bread wheat; 1.24, 3.80, 5.10, and 5.75 t/ha for durum wheat; 1.57, 2.35, 2.86, and 3.54 t/ha for faba bean, 1.36, 2.63, 3.36, and 3.74 t/ha for chickpea, and 0.64, 1.16, 1.42, and 1.58 t/ha for lentil respectively. Grain yield reductions due to the application of 2/3SI were around 10, 5, 15.6, and 10.2% of FSI on average for wheat, chickpea, faba bean, and lentils, respectively. Deficit irrigation at 2/3SI increased water productivity compared to rainfed treatments, by 200, 223, 126, 148 and 190% for bread wheat, durum wheat, faba bean, chickpea, and lentils, respectively. However, differences in total water productivity of crops grown under full irrigation compared to deficit irrigation were not significant. Irrigation water productivity ranged from 25 kg ha -1 mm -1 in wheat with 1/3SI to 10 kg ha -1 mm -1 for legumes under the FSI treatment. Unlike legumes, maximizing wheat grain yield caused a decline in water productivity.

147. No-tillage and high-residue practices reduce soil water evaporation.

• Authors:
  • Horwath, W. R.
  • Wroble, J. F.
  • Munk, D. S.
  • Wallender, W. W.
  • Singh, P. N.
  • Mitchell, J. P.
  • Hogan, P.
  • Roy, R.
  • Hanson, B. R.
• Source: California Agriculture
• Volume: 66
• Issue: 2
• Year: 2012
• Summary: Reducing tillage and maintaining crop residues on the soil surface could improve the water use efficiency of California crop production. In two field studies comparing no-tillage with standard tillage operations (following wheat silage harvest and before corn seeding), we estimated that 0.89 and 0.97 inches more water was retained in the no-tillage soil than in the tilled soil. In three field studies on residue coverage, we recorded that about 0.56, 0.58 and 0.42 inches more water was retained in residue-covered soil than in bare soil following 6 to 7 days of overhead sprinkler irrigation. Assuming a seasonal crop evapotranspiration demand of 30 inches, coupling no-tillage with practices preserving high residues could reduce summer soil evaporative losses by about 4 inches (13%). However, practical factors, including the need for different equipment and management approaches, will need to be considered before adopting these practices.

148. Natural enemies associated with cereal cover crops in olive groves.

• Authors:
  • Gonzalez, B.
  • Rodriguez, E.
  • Campos, M.
• Source: Bulletin of Insectology
• Volume: 65
• Issue: 1
• Year: 2012
• Summary: The use of cover crops is the most effective method to combat soil degradation due to erosion in olive cropping in Spain. Within the framework of Integrated Pest Management (IPM), a compelling question is how cover crops would affect elements of the olive-agroecosystem such as natural enemies. Accordingly, the objective of this study was to examine the effects of cereal cover cropping on natural enemy communities in olive groves. Samples of the anthropod communities were collected in olive groves under tillage and cover cropping systems at five different locations in the same province. Cereal cover crops significantly increased the abundance of parasitoids in the olive canopy, especially Ageniaspis fuscicollis Dalman (Hymenoptera Encyrtidae) a parasitoid of the olive moth Prays oleae Bernard (Lepidoptera Yponomeutidae), the most common insect pest of olive trees. However, parasitoid abundance and structure depended on olive grove location suggesting the importance of crop surroundings in parasitoid community dynamics. Predators numbers were slightly higher in tilled olive groves but no significant differences were found between the two soil management systems.

149. Effect of non-uniform sprinkler irrigation and plant density on simulated maize yield.

• Authors:
  • Isla, R.
  • Urrego, Y. F.
  • Salmeron, M.
  • Cavero, J.
• Source: Agricultural Water Management
• Volume: 113
• Issue: October
• Year: 2012
• Summary: Typical field conditions under sprinkler irrigation include low irrigation uniformity and non-uniform plant density, which can affect the crop yield and the environmental impact of irrigation. The effect of the uniformity of sprinkler irrigation and plant density on the variability of maize grain yield under semi-arid conditions was evaluated, and the relevance of the spatial variability of these two variables on the simulation of maize grain yield was tested with the DSSAT-CERES-Maize model (V 4.5). Experimental field data from three maize growing seasons (2006, 2009 and 2010) with nighttime or daytime sprinkler irrigation were used to test the model performance. Yield, irrigation depths and plant density distribution were measured in 18 m * 18 m plots divided in 25 sub-plots. Regression analysis showed that the variability of plant density and seasonal irrigation depth (due to irrigation non-uniformity) was able to explain from 28 to 77% of the variability in maize grain yield for the experiments with a relatively high coefficient of uniformity (CU) (73-84%) and high plant density (more than 74,844 plants ha -1). Taking into account irrigation depth distribution improved maize yield simulations compared to simulations with the average irrigation water applied. The root mean square error ( RMSE) decreased from 637 to 328 kg ha -1. Maize yield was over-predicted by 3% when irrigation depth distribution was not considered. Including plant density distribution in the simulations did not improve maize yield simulations. The simulated decrease in maize yield with decreasing CU of irrigation from 100 to 70% varied from year to year and caused reductions in yield ranging from 0.75 to 2.5 Mg ha -1. The ability of the model to simulate CU effects on maize yield is shown.

150. Agronomic potential of vetch landraces from Jordan

• Authors:
  • Saoub, H. M.
  • Akash, M. W.
  • Ayad, J. Y.
• Source: Research on Crops
• Volume: 13
• Issue: 1
• Year: 2012
• Summary: In Jordan, the improvement of vetch production is becoming one of the main objectives as its growing areas are decreasing either because of environmental or cropping system changes. However, there is no literature concerning the assessment of genetic diversity of vetches landraces that harbour important genes for the development of new adapted varieties. The present study aimed at collecting, evaluating and characterizing vetch landraces covering different parts of Jordan. Twenty-six vetch landraces were collected from different parts of Jordan during a period extended from April to May in 2006-07 growing season and assessed in the field during 2008-09 growing season. The experiment was conducted at three stations (Ghwier Agricultural Research Station, Rabba Agricultural Research Station and Jubeiha Agricultural Research Station, The University of Jordan). Results indicated that grain yield of Vicia erivillia landraces was higher than grain yield of Vicia sativa landraces, regardless of the growing location. However, biological yield obtained from V. sativa entries [671 kg/ha (entry no. 6) upto 2514 kg/ha (entry no. 1)] was higher than that obtained from V. erivillia entries [536 kg/ha (entry no. 10) upto 2125 kg/ha (entry no. 23)]. Similar trend was shown for straw yield where V. sativa entries had more vegetative growth compared to V. erivillia entries. These differences attributed to the dissimilarity in genetic make-up of the two species. For example, some researchers mention that V. erivillia produces more grain yield due to its ability to tolerate drought when compared to V. sativa. The identification of these superior adapted local landraces is the first step in fulfilling the objective of the national vetch breeding programme.