- Authors:
- Bernardi, A.
- Harden, S.
- Wilson, B.
- Young, R.
- Source: Australian Journal of Soil Research
- Volume: 47
- Issue: 3
- Year: 2009
- Summary: Australian agriculture contributes an estimated 16% of all national greenhouse gas emissions, and considerable attention is now focused on management approaches that reduce net emissions. One area of potential is the modification of cropping practices to increase soil carbon storage. This paper report short-medium term changes in soil carbon under zero tillage cropping systems and perennial vegetation, both in a replicated field experiment and on nearby farmers' paddocks, on carbon-depleted Black Vertosols in the upper Liverpool Plains catchment. Soil organic carbon stocks (C S ) remained unchanged under both zero tillage long fallow wheat ( Triticum aestivum)-sorghum ( Sorghum) rotations and zero tillage continuous winter cereal in a replicated field experiment from 1994 to 2000. There was some evidence of accumulation of C S under intensive (>1 crop/year) zero tillage response cropping. There was significant accumulation of C S (~0.35 tonnes/ha/year) under 3 types of perennial pasture, despite removal of aerial biomass with each harvest. Significant accumulation was detected in the 0-0.1, 0.1-0.2, and 0.2-0.4 m depth increments under lucerne and the top 2 increments under mixed pastures of lucerne and phalaris and of C3 and C4 perennial grasses. Average annual rainfall for the period of observations was 772 mm, greater than the 40-year average of 680 mm. A comparison of major attributes of cropping systems and perennial pastures showed no association between aerial biomass production and accumulation rates of C S but a positive correlation between the residence times of established plants and accumulation rates of C S . C S also remained unchanged (1998/2000-07) under zero tillage cropping on nearby farms, irrespective of paddock history before 1998/2000 (zero tillage cropping, traditional cropping, or ~10 years of sown perennial pasture). These results are consistent with previous work in Queensland and central western New South Wales suggesting that the climate (warm, semi-arid temperate, semi-arid subtropical) of much of the inland cropping country in eastern Australia is not conducive to accumulation of soil carbon under continuous cropping, although they do suggest that C S may accumulate under several years of healthy perennial pastures in rotation with zero tillage cropping.
- Authors:
- Zhu, C.
- He, K.
- Pan, M.
- Mao, G.
- Pan, G.
- Zheng, Y.
- Source: Guizhou Agricultural Sciences
- Issue: 1
- Year: 2009
- Summary: This study investigated the effects of different intercropping and interplanting patterns of green manure on soil fertility in Guizhou, China. The results showed that maize yield in improved soil fertility areas under 1:1 application ratio between organic and inorganic fertilizer averagely increased by 23.05% (102.5 kg/667m 2) compared with the conventional application pattern. The yields of the potato-green manure-maize pattern, rape-green manure-maize pattern and wheat-green manure-maize pattern increased by 51.2-66.0 kg/667m 2, 146.1 kg/667 m 2 and 146.7 kg/667 m 2, respectively compared with the conventional application pattern. The soil organic matter, total nitrogen, alkaline hydrolysis nitrogen, active P and active K content in improved soil fertility areas averagely increased by 0.23%, 0.033%, 23.23 mg/kg, 1.5 mg/kg and 17.75 mg/kg respectively and the soil fertility was increased to varying degrees. The high maize yield depends on its strong and high plants and better economic characters.
- Authors:
- Source: Field Crops Research
- Volume: 112
- Issue: 2/3
- Year: 2009
- Summary: Preharvest sprouting (PHS) is a risk factor in winter cereal farming in certain environments as even mild sprouting affects the suitability of wheat for end-use products. This is because even mild sprouting affects the suitability of wheat for end-use products. The extent of PHS is hard to predict. To establish a quantitative relationship between PHS and different climatic characteristics, eighteen winter wheat cultivars were planted in three regions representative of the wheat growing conditions of the Free State Province of South Africa over four years. Climatic characteristics during six environmental periods were investigated, namely planting to harvest (PH), anthesis to harvest (AH), grain filling (GF), 14 days prior to physiological maturity (14M) and 10 and 20 days prior to harvest (10H and 20H) respectively. These data sets were correlated with PHS resistance determined in a rain simulator to determine if climate during various stages of grain development had an effect on the expression of dormancy and subsequent PHS. Principal component analysis (PCA) on mean PHS values identified three distinct groupings of cultivars, ranging from PHS susceptible to PHS resistant. A fairly strong positive correlation ( r=0.715, P=0.008) was found between PHS and minimum temperature during grain filling. Large variations in PHS values were also observed between the various cultivars, indicating that certain cultivars, such as Caledon, Gariep, Limpopo, Matlabas, PAN 3118, PAN 3120, PAN 3377 and SST 334, are more sensitive to environmental effects than others and that the variation in cultivar PHS is not consistent across sites and years.
- Authors:
- Hill, J.
- Jacobs, J. L.
- Jenkin, T.
- Source: Animal Production Science
- Volume: 49
- Issue: 7
- Year: 2009
- Summary: The efficient production and subsequent utilisation of home-grown forage is seen as the cornerstone of profitability of the dairy industry as it leads to lower unit costs of milk production compared with purchased forage or grain supplements. Cereals such as wheat ( Triticum aestivum L.), oats ( Avena sativa L.) and triticale ( Triticum * Triticosecale) all have the potential to produce high forage dry matter (DM) yields. These forages are not widely grown within dryland Australian dairy systems and there is a paucity of information on both the agronomic requirements and subsequent ensiling and feed-out management under these conditions. The experiment reported in this paper examines the DM yield, nutritive and ensiling characteristics of three small-grain cereals (triticale, wheat and oats) cut at various stages of development and ensiled with or without silage additives. We hypothesised that: (1) delaying harvesting until later stages of growth would result in higher DM yields, but negatively impact on both nutritive and fermentation characteristics of subsequent silages; (2) ensiling wilted material at earlier harvests would improve fermentation characteristics compared with direct ensiled material; and (3) the use of silage additives at all harvests would improve fermentation characteristics of resultant silages compared with untreated silages. Apart from winter oats, the estimated metabolisable energy of forages was highest at the boot stage of growth, declined during anthesis and then rose again during milk and soft-dough stage of growth. The crude protein content of forages declined with maturity, with final values at soft dough below 90 g/kg DM. Neutral detergent fibre content was highest at anthesis and then declined, with lowest values observed at soft dough (497-555 g/kg DM). In the majority of cases silages were well preserved, with direct ensiled material having pH values generally below 4.5 and wilted material below 5.0, with limited proteolysis as assessed by ammonia-N contents in the range of 5-15% of total-N. The production of volatile fatty acids and lactic acid was influenced by wilting and the use of additives. Generally, wilted silages fermented less than the corresponding direct ensiled forages, whereas the use of Sil-All 4*4 additive resulted in a lactic acid-dominant fermentation compared with LaSil additive, which resulted in a greater proportion of acetic acid as an end product of fermentation. The findings of the present study highlight the potential of forage cereals to produce high DM yields for whole crop cereal silage. The timing of harvest directly influences nutritive characteristics of forages for ensiling. The use of silage additives can assist in controlling fermentation pathways during ensilage, ensuring the production of silages with fermentation attributes more likely to lead to higher intakes when fed to animals.
- Authors:
- Kelly,K.
- Graham,J.
- Biswas,W. K.
- John,M. B.
- Source: 6th Australian Conference on Life Cycle Assessment
- Year: 2009
- Authors:
- Source: Tropical Grasslands
- Volume: 43
- Year: 2009
- Summary: Agriculture is responsible for a significant proportion
of total anthropogenic greenhouse gas
emissions (perhaps 18% globally), and therefore
has the potential to contribute to efforts to
reduce emissions as a means of minimising the
risk of dangerous climate change. The largest
contributions to emissions are attributed to ruminant
methane production and nitrous oxide from
animal waste and fertilised soils. Further, livestock,
including ruminants, are an important component
of global and Australian food production
and there is a growing demand for animal protein
sources. At the same time as governments and
the community strengthen objectives to reduce
greenhouse gas emissions, there are growing concerns
about global food security. This paper provides
an overview of a number of options for
reducing methane and nitrous oxide emissions
from ruminant production systems in Australia,
while maintaining productivity to contribute to
both objectives. Options include strategies for
feed modification, animal breeding and herd
management, rumen manipulation and animal
waste and fertiliser management. Using currently
available strategies, some reductions in emissions
can be achieved, but practical commercially
available techniques for significant reductions in
methane emissions, particularly from extensive
livestock production systems, will require greater
time and resource investment. Decreases in the
levels of emissions from these ruminant systems
(i.e., the amount of emissions per unit of product
such as meat) have already been achieved. However,
the technology has not yet been developed
for eliminating production of methane from the
rumen of cattle and sheep digesting the cellulose
and lignin-rich grasses that make up a large part
of the diet of animals grazing natural pastures,
particularly in arid and semi-arid grazing lands.
Nevertheless, the abatement that can be achieved
will contribute significantly towards reaching
greenhouse gas emissions reduction targets
- Authors:
- Blignaut, J.
- Ueckermann, L.
- Aronson, J.
- Source: South African Journal of Science
- Volume: 105
- Issue: 1/2
- Year: 2009
- Summary: South Africa in general has been approximately 2% hotter and at least 6% drier over the ten years between 1997 and 2006 compared to the 1970s. The use of water has also increased greatly over this same period. By 2000, 98.6% of that year's surface water yield and 41% of the annual utilisable potential of groundwater was allocated to use. Irrigation agriculture, comprising 60% of total consumption, is by far the largest single consumer of water. Given these climatic and water use changes as a backdrop, we employed a panel data econometric model to estimate how sensitive the nation's agriculture may be to changes in rainfall. Net agricultural income in the provinces, contributing 10% or more to total production of both field crops and horticulture, is likely to be negatively affected by a decline in rainfall, especially rain-fed agriculture. For the country as a whole, each 1% decline in rainfall is likely to lead to a 1.1% decline in the production of maize (a summer grain) and a 0.5% decline in winter wheat. These results are discussed with respect to both established and emerging farmers, and the type of agriculture that should be favoured or phased out in different parts of the country, in view of current and projected trends in climate, increasing water use, and declining water availability.
- Authors:
- Issue: 05-09
- Year: 2009
- Summary: This report incorporates higher energy prices estimated by CRA International under H.R. 2454 (The American Clean Energy and Security Act of 2009) on Missouri crop production costs. This analysis uses current 2009 Missouri crop production cost estimates as the base and examines the level of these production costs in 2020, 2030, 2040 and 2050 assuming these production costs change only as a result of the higher energy costs estimated by CRA International under H.R. 2454. Using the 11, 34 and 45 percent increases found by CRA International in motor fuel, natural gas and electricity prices, respectively, by 2050 as a result of H.R. 2454, estimated Missouri crop operating costs increase by 8.1, 8.8, 4.4 and 10.4 percent for dryland maize, irrigated maize, soyabeans and wheat, respectively.
- Authors:
- Hunt, J. R.
- Dalgliesh, N. P.
- McCown, R. L.
- Whish, J. P. M.
- Robertson, M. J.
- Foale, M. A.
- Poulton, P. L.
- Rees, H. van
- Carberry, P. S.
- Hochman, Z.
- Source: Crop & Pasture Science
- Volume: 60
- Issue: 11
- Year: 2009
- Summary: Crop simulation models relevant to real-world agriculture have been a rationale for model development over many years. However, as crop models are generally developed and tested against experimental data and with large systematic gaps often reported between experimental and farmer yields, the relevance of simulated yields to the commercial yields of field crops may be questioned. This is the third paper in a series which describes a substantial effort to deliver model-based decision support to Australian farmers. First, the performance of the cropping systems simulator, APSIM, in simulating commercial crop yields is reported across a range of field crops and agricultural regions. Second, how APSIM is used in gaining farmer credibility for their planning and decision making is described using actual case studies. Information was collated on APSIM performance in simulating the yields of over 700 commercial crops of barley, canola, chickpea, cotton, maize, mungbean, sorghum, sugarcane, and wheat monitored over the period 1992 to 2007 in all cropping regions of Australia. This evidence indicated that APSIM can predict the performance of commercial crops at a level close to that reported for its performance against experimental yields. Importantly, an essential requirement for simulating commercial yields across the Australian dryland cropping regions is to accurately describe the resources available to the crop being simulated, particularly soil water and nitrogen. Five case studies of using APSIM with farmers are described in order to demonstrate how model credibility was gained in the context of each circumstance. The proposed process for creating mutual understanding and credibility involved dealing with immediate questions of the involved farmers, contextualising the simulations to the specific situation in question, providing simulation outputs in an iterative process, and together reviewing the ensuing seasonal results against provided simulations. This paper is distinct from many other reports testing the performance and utility of cropping systems models. Here, the measured yields are from commercial crops not experimental plots and the described applications were from real-life situations identified by farmers. A key conclusion, from 17 years of effort, is the proven ability of APSIM to simulate yields from commercial crops provided soil properties are well characterised. Thus, the ambition of models being relevant to real-world agriculture is indeed attainable, at least in situations where biotic stresses are manageable.
