Pea variety tolerances to herbicides

88ME118. This site was variably infested with a population of wild oats and self-sown cereals

Tolerance of recommended cereal varieties of new herbcides

88EC28, 88SC31, 88N73

Tolerance of cereal varieties to herbicides

Tolerance of current cereal varieties to new herbicides, 89EC21, 89N27, 89SC15. Tolerance of new cereal varieties to current herbicides, 89EB19, 89EC20, 89N28, 89SC16. Tolerance of wheat varieties to Metribuzin and Pendimethalin, 89EC22, 89WH58. Tolerance of wheat to herbicide tank mixes for grass and broadleaf weed control in cereals, 89WH86. Grasp efficacy and tolerance, 89C22, 89GE93. Tolerance of field peas to herbicides, 89KA64, 89M56. Tolerance of pasture legume varieties to herbicides, 89KA76. Crop establishment using residual herbicides for weed control, 89NA66

Agricultural greenhouse gas emissions

Agriculture contributes 15.5 per cent of Australia’s emissions (Figure 1), largely due to methane, from ruminant livestock digestion, nitrous oxide from soils and carbon dioxide from fossil fuel use (Australian National Greenhouse Accounts 2011; ABARES 2011). This bulletin identifies current ways to reduce greenhouse gas emissions from Australian agriculture.https://researchlibrary.agric.wa.gov.au/bulletins/1176/thumbnail.jp

Transformative and systemic climate change adaptations in mixed crop-livestock farming systems

Mixed crop-livestock farming systems provide food for more than half of the world's population. These agricultural systems are predicted to be vulnerable to climate change and therefore require transformative adaptations. In collaboration with farmers in the wheatbelt of Western Australia (WA), a range of systemic and transformative adaptation options, e.g. land use change, were designed for the modelled climate change projected to occur in 2030 (0.4–1.4° increase in mean temperature). The effectiveness of the adaptation options was evaluated using coupled crop and livestock biophysical models within an economic and environmental framework at both the enterprise and farm scales. The relative changes in economic return and environmental variables in 2030 are presented in comparison with a baseline period (1970–2010). The analysis was performed on representative farm systems across a rainfall transect. Under the impact of projected climate change, the economic returns of the current farms without adaptation declined by between 2 and 47%, with a few exceptions where profit increased by up to 4%. When the adaptations were applied for 2030, profit increased at the high rainfall site in the range between 78 and 81% through a 25% increase in the size of livestock enterprise and adjustment in sowing dates, but such profit increases were associated with 6–10% increase in greenhouse gas (GHG) emissions. At the medium rainfall site, a 100% increase in stocking rate resulted in 5% growth in profit but with a 61–71% increase in GHG emissions and the increased likelihood of soil degradation. At the relatively low rainfall site, a 75% increase in livestock when associated with changes in crop management resulted in greater profitability and a smaller risk of soil erosion. This research identified that a shift toward a greater livestock enterprises (stocking rate and pasture area) could be a profitable and low-risk approach and may have most relevance in years with extremely low rainfall. If transformative adaptations are adopted then there will be an increased requirement for an emissions control policy due to livestock GHG emissions, while there would be also need for soil conservation strategies to be implemented during dry periods. The adoption rate analysis with producers suggests there would be a greater adoption rate for less intensified adaptations even if they are transformative. Overall the current systems would be more resilient with the adaptations, but there may be challenges in terms of environmental sustainability and in particular with soil conservation

Climate change impact on Western Australian mixed farm systems

Primary enterprises are expected to contend with more frequent climate crises, environmental degradation and even climate-related regulatory change (IPCC, 2014). These stressors occur against an existing backdrop of conventional drivers including economic, biophysical, institutional, cultural and political pressures (Marshall et al., 2012). Australia’s primary industries have historically operated in a highly variable climate and this has posed significant challenges to production, requiring sound and responsive risk management practices. Climate change, brings with it a number of new challenges not yet accounted for by Australian primary producers, and so understanding the scale of these impacts is of importance in undertsanding the changing nature of agricultural risk in the near future. Western Australia with about 4 million ha of wheat production is a major contributor to the Australian agrifood sector and economy. Like cereal production, pastures in WA play a major role in agricultural enterprises and contribute over $3 billion annually through animal production, improvements to crop rotations and conserved fodder (The Department of Agriculture and Food, 2014). Farming profitably in the Western Australia in recent years has been a challenge due in part to declines in annual rainfall as well as exposure to both heat and cold teperature extremes (McConnell & O’Hare, 2013), although lower production might be still profitable. Climate drives the productivity, profitability and environmental health of these systems as they often have to respond to low and variable rainfall. Here we identify the likely effect of climate change in 2030 on mixed farm systems of the Western Australia across a climate transect in terms of production, profit, and environmental impacts for projected climate scenarios in 2030 relative to the baseline of 1980-1999. This work will give insight for designing strategies to respond to changes in climate such as optimized shift towards more intensive livestock systems, dual-purpose cropping, etc

Systemic adaptations to climate change in Western Australian mixed farm systems

Australia’s primary industries have historically operated in a highly variable climate. This has posed significant challenges to production, requiring sound and responsive risk management practices. Climate change has, and will, introduce even greater challenges. This means that there is a clear need to continue to assess the opportunities for farmers to improve how they respond to climate variability and changes. We built representative mixed farm systems (using AusFarm) across climate gradients to investigate likely effect of climate change and variability and systemic adaptations to explore system’s resilience, to enhance productivity under climate variability, and change by 2030. We used AusFarm to build mixed farm systems. Model inputs were derived by consulting with producers and models performance was validated against survey data. For a climate gradient of 335-215 mm rainfall (Apr-Oct) in Western Australia, we evaluated long term average effectiveness of changes in planting date, fertilizer application rate, crop and stubble grazing, and stocking rates (SR) for 2002-2012 as baseline. To assess the impact of climate change, we used two high-emissions CMIP3 scenarios (A1FI and A2) with high and medium sensitivity and six global climate models projected climate for 2030. In 2030 and in a relatively medium rainfall region (MR) of the climate gradient, wheat, barley, canola production changed by +6%, +2%, and -2% on average while meat and wool production increased by 1% and 2%. In 2030, and in lower rainfall (LR) end of gradient, wheat, barley, canola, and lupine production changed by -8%, -2%, -11% and -16% while meat and wool production changed by -2% and -4%. In 2030, GHG emissions changed by -10% for LR and -5% for MR under current management. In addition to systemic combination of options described above, we evaluated a range of climate adaptation packages, which were determined in collaboration with stakeholders. These adaptation packages designed specifically for each region to reduce negative impact and risk of climate change and benefit from likely opportunities. Alteration of the crop-livestock balance is an adaptation that can compensate negative impact of climate change by reduction in business risk. These were evaluated through a package with elements of optimizing area proportions of cropping and pasture either by changing the relative areas of existing crop & pasture sequences or the relative length of crop & pasture phases, optimizing stocking rate, and adjustments in livestock joining and sale dates. We designed low-variability to high-intensity mixed farming as adaptation packages optimised for different risk and return management approaches. Overall, financially optimal systemic adaptations were projected to offset negative impact of climate change on production and profitability of whole farm system in 2030 at majority of sites. This would require for practice and land use change to cope with changes in climate

Crop Updates 1999 - Oilseeds

This article contains eighteen papers INTRODUCTION, Paul Carmody, Agriculture Western Australia PLENARY SESSION Transgenic canola in Western Australia: Outlook and challenges, Phil Salisbury, University of Melbourne Farming system issues for herbicide tolerant canola, Rick Madin, Rick Madin and Associates, David Bowran, Agriculture Western Australia Beating blackleg in 1999, Martin Barbetti, Ravjit Khangura, Paul Carmody, Graham Walton, Agriculture Western Australia The Mustard Industry in Australia – Opportunities for a new oilseed, Phil Parker, NSW Agriculture Management of blackleg with fungicides, Ravjit Khangura and Martin Barbetti, Agriculture Western Australia Effect of aphid feeding damage on canola yields in 1998, Francoise Berlandier and Linnet Cartwright, Agriculture Western Australia Post-anthesis duration and rainfall affect oil content of canola, Ping Si, University of West Australia, Graham Walton, Agriculture Western Australia, Nick Galwey and David Turner, University of West Australia Canola responded to high rates of fertiliser in 1998, Wayne Pluske, CSBP Impact of agronomic practices on canola quality, Graham Walton, Agriculture Western Australia Survey reveals widespread infection with two virus diseases in Western Australian canola crops, Roger Jones and Brenda Coutts, Agriculture Western Australia Calculating canola yields and oil contents as a function of soil and fertiliser nitrogen supply, Bill Bowden and Isabel Arevalo-Vigne, Agriculture Western Australia Canola benchmarks 1997/98 – Central Eastern District, Jeff Russell, Agriculture Western Australia Seeding rate affects the yield and some architectural features of canola, Syed H. Zaheer, Nick W. Galwey and David Turner, University of Western Australia Foliar applied fungicides for blackleg, Andrew Simon and Art Diggle, Agriculture Western Australia Farm based demonstration 1998 canola N – Wheel evaluation, Jeff Russell, Agriculture Western Australia Effect of sowing date on seed yield of canola, Dave Eksteen, Agriculture Western Australia Investigating water use of summer crops on the South Coast of Western Australia, Arjen Ryder, Agriculture Western Australia, Bill Crabtree, Western Australia No Till Farming Association, Serena Wyatt, Catchment Landcare Coordinator, Wellstead, Jim Baily, Subasio Downs, Wellstead INTRODUCTION, Paul Carmody, Agriculture Western Australia PLENARY SESSION Transgenic canola in Western Australia: Outlook and challenges, Phil Salisbury, University of Melbourne Farming system issues for herbicide tolerant canola, Rick Madin, Rick Madin and Associates, David Bowran, Agriculture Western Australia Beating blackleg in 1999, Martin Barbetti, Ravjit Khangura, Paul Carmody, Graham Walton, Agriculture Western Australia The Mustard Industry in Australia – Opportunities for a new oilseed, Phil Parker, NSW Agriculture Management of blackleg with fungicides, Ravjit Khangura and Martin Barbetti, Agriculture Western Australia Effect of aphid feeding damage on canola yields in 1998, Francoise Berlandier and Linnet Cartwright, Agriculture Western Australia Post-anthesis duration and rainfall affect oil content of canola, Ping Si, University of West Australia, Graham Walton, Agriculture Western Australia, Nick Galwey and David Turner, University of West Australia Canola responded to high rates of fertiliser in 1998, Wayne Pluske, CSBP Impact of agronomic practices on canola quality, Graham Walton, Agriculture Western Australia Survey reveals widespread infection with two virus diseases in Western Australian canola crops, Roger Jones and Brenda Coutts, Agriculture Western Australia Calculating canola yields and oil contents as a function of soil and fertiliser nitrogen supply, Bill Bowden and Isabel Arevalo-Vigne, Agriculture Western Australia Canola benchmarks 1997/98 – Central Eastern District, Jeff Russell, Agriculture Western Australi

Crop Updates 2000 - Weeds

This session covers thirty six papers from different authors: INTRODUCTION, Vanessa Stewart Agriculture Western Australia INTEGRATED WEED MANAGEMENT Effect of seeding density, row spacing and Trifluralin on the competitive ability of Annual Ryegrass in a minimum tillage system, David Minkey, Abul Hashem, Glen Riethmuller and Martin Harries, Agriculture Western Australia High wheat seeding rates coupled with narrow row spacing increases yield and suppresses grass, Peter Newman1 and Cameron Weeks2,1Agronomist, Elders Limited 2Mingenew/Irwin Group Resistant ryegrass management in a wheat – lupin rotation, Abul Hashem, Harmohinder S. Dhammu, Aik Cheam, David Bowran and Terry Piper, Agriculture Western Australia Integrated weed management – Will it work with my rotation? Alexandra Wallace, Agriculture Western Australia Long term herbicide resistance trial – Mingenew, Peter Newman Elders, Cameron Weeks Mingenew-Irwin Group Is two years enough? Bill Roy, Agricultural Consulting and Research Services The fate of ryegrass seed when sheep graze chaff cart heaps, Keith L. Devenish1 and Lisa J. Leaver2 1 Agriculture Western Australia, 2Curtin University of Technology, Muresk Institute of Agriculture Can blanket wiping and crop topping prevent seed set of resistant wild radish and mustard? StAbul Hashem, Harmohinder Dhammu, Vanessa Stewart, Brad Rayner and Mike Collins, Agriculture Western Australia The value of green manuring in the integrated management of ryegrass, Marta Monjardino1,2, David Pannell2, Stephen Powles1 ,1Western Australia Herbicide Resistance Initiative, 2Agricultural and Resource Economics, University of Western Australia Some ways of increasing wheat competitiveness against ryegrass,, Mike Collins Centre for Cropping Systems, Agriculture Western Australia WEED BIOLOGY Understanding and driving weed seed banks to very low levels, Sally Peltzer, Agriculture Western Australi HERBICIDE RESISTANCE Cross resistance of chlorsulfuron-resistant wild radish to imidazolinones, Abul Hashem, Harmohinder Dhammu and David Bowran, Agriculture Western Australia Investigation of suspected triazine resistant ryegrass populations for cross-resistance and multiple resistance to herbicides, Michael Walsh, Charles Boyle and Stephen Powles, Western Australian Herbicide Resistance Initiative, University of Western Australia Genetics and fitness of glyphosate resistant ryegrass, S. Powles1, P. Neve1, D. Lorraine-Colwill2, C. Preston2 ,1WAHRI, University of Western Australia 2 CRC Weed Management Systems, University of Adelaide Managing herbicide resistance – the effect of local extinction of resistance genes, Art Diggle1, Paul B. Neve2, Stephen B. Powles2 ,1Agriculture Western Australia, 2WAHRI, Faculty of Agriculture, University of Western Australia The double knock - the best strategy for conserving glyphosate susceptibility? Paul B. Neve1, Art Diggle2, Stephen B. Powles1,1WAHRI, Faculty of Agriculture, University of Western Australia, 2Agriculture Western Australia Wild radish had evolved resistance to triazines, Abul Hashem, Harmohinder S. Dhammu, David Bowran and Aik Cheam, Agriculture Western Australia Ryegrass resistance in Western Australia – where and how much? Rick Llewellyn and Stephen Powles, Western Australian Herbicide Resistance Initiative, Faculty of Agriculture, University of Western Australia Wild radish herbicide resistance survey, Michael Walsh, Ryan Duane and Stephen Powles, Western Australian Herbicide Resistance Initiative, University of Western Australia Knockdown resistance in the Western Australian wheatbelt – a proposed survey, Paul B. Neve1, Abul Hashem2, Stephen B. Powles1,1Western Australian Herbicide Resistance Initiative, University of Western Australia, 2Agriculture Western Australia Diflufenican resistant wild radish, Aik Cheam, Siew Lee, David Bowran, David Nicholson and Abul Hashem, Agriculture Western Australi Multiple resistance to triazines and diflufenican further complicates wild radish control, Aik Cheam, Siew Lee, David Bowran, David Nicholson and Abul Hashem, Agriculture Western Australia HERBICIDE TOLERANCE 25. Herbicide tolerance of lupins, Terry Piper, Weed Science Group, Agriculture Western Australia 26. Tanjil lupins will tolerate metribuzin under the right conditions, Peter Newman, Agronomist Elders Limited and Cameron Weeks, Mingenew/Irwin Group 27. Herbicide damage does not mean lower yield in Lupins, Peter Carlton, Trials Coordinator, Elders Limited 28. Herbicide tolerance of new pea varieties, Dr Terry Piper, Agriculture Western Australia 29. Herbicide tolerance of (waterlogged) wheat, Dr Terry Piper, Agriculture Western Australia 30. Wheat tolerance trials – Mingenew 1999, Peter Newman1, Cameron Weeks2 and Stewart Smith3,1Elders, Mingenew, 2Mingenew-Irwin Group,3Agriculture Western Australia ISSUES OF TRIFLURALIN USE 31. Trifluralin works better on ryegrass when no-tilling into thick wheat stubbles as granules, or mixed with limesand, Bill Crabtree, WANTFA Scientific Officer 32. Increasing trifluralin rate did not compensate for delaying incorporation, Bill Crabtree, WANTFA Scientific Officer 33. Poor emergence survey, 1999, Terry Piper, Weed Science Group, Agriculture Western Australia HERBICIDES – ISSUES AND OPTIONS 34. AFFINITY 400DF – A new herbicide with a new mode of action (Group G) for Broadleaf Weed Control in Cereals, Gordon Cumming, Technical Officer, Crop Care Australasia 35 Herbicide screening for Marshmallow, David Minkey1 and David Cameron2,1Agriculture Western Australia, 2Elders Ltd, Merredin 36. The control of Capeweed in Clearfield Production System for Canola, Mike Jackson and Scott Paton, Cyanamid Agriculture Pty Ltd 37.Effect of herbicides Tordonä 75D and Lontrelä,used for eradication of Skeleton Weed, on production of Lupins I the following seasons, John R. Peirce and Brad J. Rayner, Agriculture Western Australia INDUSTRY PROTECTION 38. Graingaurd – Opportunities for agribusiness to help protect the West Australian grains industry, Greg Shea, Executive Officer, GrainGuard Agriculture Western Australi

Crop Updates 2011 - Cereals

This session covers eleven papers from different authors: OPENING, NEW CROP VARIETIES & DECISION SUPPORT Opening 1. Overview of the 2010 season, David Bowran, Director, Practice and Systems Innovation, Department of Agriculture and Food, 2. My experience in a drought as a farmer and consultant, Bill Crabtree, Morawa, Western Australia 3. Meeting the productivity and sustainability challenges to Australian agriculture until 2030, Peter Carberry, CSIRO Sustainable Agriculture Flagship New Crop Varieties 4. National Variety Trials (NTV) wheat variety performance – captivity vs broadacre, Peter Burgess, Kalyx Agriculture 5. WALAN2289 – a new lupin variety to replace Mandelup in the system, Bevan Buirchell, Department of Agriculture and Food 6. The strengths and pitfalls of different grades of new wheat varieties in Western Australia Ben Curtis, Sarah Ellis, Brenda Shackley, Christine Zaicou, Department of Agriculture and Food, 7. Yield performance of temperate and tropical rice varieties in the Ord River Irrigation Areas (ORIA) Siva Sivapalan, Penny Goldsmith and Gae Plunkett, Department of Agriculture and Food Decision Support 8. A new phenology model (DM) for wheat, Darshan Sharma, Mario D’Antuono, Brenda Shackley, Christine Zaicou, Ben Curtis, Department of Agriculture and Food 9. PeatFax Map and the Weed Seed Wizard: tools to help with crop protection, Art Diggle1, Peter Mangano1, Sally Peltzer1, Michael Renton2, Bill Macleod1, Fumie Horiuchi1, George Wyatt1 1Department of Agriculture and Food, 2University of Western Australia 10. Soil management calculator for predicting phosphorus losses under cropping systems in Western Australia, Geoff Anderson1, Richard Bell2, Ross Brennan1 and Wen Chen2, 1Department of Agriculture and Food, 2School of Environmental Science, Murdoch University 11. Tools to assist growers understand the impacts of management decisions in the high rainfall zone, Penny Riffkin, Department of Primary Industries, Victoria, Hamilto