Investment in science and industry development key to profitable agrifood sector 2

Micronutrients are essential for crop production.

The interest in micronutrients fertiliser for crop production has been due to the increased use of one-pass seeding equipment. Copper (Cu) and zinc (Zn) are immobile in soils, availability and uptake by plant roots depends upon roots growing to the particle of micronutrient in the soil. Traditionally cultivation has distributed the micronutrients through the soil and increased the likelihood of root interception Cu and Zn particles. In no-till systems, there is limited physical distribution of micronutrient fertiliser particles.

The maintenance strategy, where small amounts of micronutrients are applied each year, has gained popularity in recent years. The application of small amounts in compound fertiliser in cropping can be used to distribute Cu and Zn through soil. The maintenance strategy works provided micronutrient levels in the soil are already adequate. If the maintenance strategy works it will be because Cu and Zn are applied in different positions each year and distributed through the soil to some extent by subsequent sowings.

Availability of micronutrients and effectiveness of fertilisers depend on many seasonal and environmental conditions. However, the pH of soil is an important factor affecting the availability of Zn, Cu, manganese (Mn) and molybdenum (Mo). As soil pH increases, Zn, Cu and Mn are more strongly fixed by soil constituents (e.g. clay) and hence the availability to plants declines. However, Mo availability to plants increases as the soil pH increases. Acidic soils, with soil pH values below about 4.7 are frequently Mo deficient for cereal production. A liming program to increase soil pH decreases the need for frequent applications of Mo fertiliser in cropping systems. The field research is ongoing and will be used to provide guidelines for decision making on micronutrients for grain growers and advisors.

This project will produce clear guidelines for management of micronutrient disorders for mainly wheat in WA. The guidelines will be based on data that has been objectively tested for its relevance to modern cropping systems for current technologies and economic circumstances.

Highlights box

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  There is increasing concern that the packages developed for micronutrient fertiliser advice may not be adequate for current cropping systems, or for new areas of cropping that are quite different to the areas where the recommendations were originally developed.
  
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  There is also increasing concern that micronutrient supplies from the soil may no longer be adequate for cropping systems that are more productive, more intensive and more reliant on supplies of fertiliser N and P.
  
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  Mo deficiency now appears on soils that have acidified. Approximately 12% of soils have a soil pH less 4.5 (0 to 10 cm depth) and low extractable Al where large responses to Mo fertilisers for crop production have been measured.
  

Funding and Collaborators

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Crop protection portfolio

Crop pests (weeds, invertebrate pests and diseases) cost WA grain growers millions of dollars a year in control strategies and lost production. Annual losses to the Australian grains industry due to disease were estimated to be over $1.3 billion per annum in 2009 with potential losses of over $4 billion. Associated costs for invertebrate pests were estimated to be over $350 million in 2013. The current (2016) estimated annual cost of weeds to Australian grain growers is $3.3 billion.

In 2015/16, $7.7 million was invested in R&D through the crop protection portfolio by engaging 51 staff on 26 projects across all cropping regions from Geraldton to Esperance. These projects recommend management strategies to minimise the impact of pests on crop yields and reduce the potential downgrading of grain due to damage or contamination.

Together, the projects examine the biology of individual species, develop management recommendations and integrated management packages, decision support tools and new techniques to enable grain growers to quickly and effectively manage these pests.

Crop pathology R&D concentrates on foliar and root diseases caused by fungi, viruses and nematodes, including sclerotinia and blackleg (canola), powdery mildew and rust (wheat and barley), crown rot and rhizoctonia, bean yellow mosaic virus (pulses) and root-lesion nematodes. There is also a focus on quantitative epidemiology, crop disease modelling and risk forecasting, in addition to evaluating crop varietal responses to disease enabling growers to make informed crop management decisions.

Invertebrate pest R&D addresses aphids, red-legged earth mites, slugs and snails. We also investigate the use of beneficial species and how they can be used to keep pest populations below damaging levels.

With a shifting climate and a change in farming systems, the challenge of controlling herbicide resistant and emerging weeds such as fleabane and brome grass is examined in several weed projects.

Spray application technology and pesticide delivery to minimise the risk of pesticide spray drift while optimising canopy coverage and penetration and the herbicide tolerance of new crops is also being researched.

Current populations and distribution of each pest (including insects, crop diseases and weeds) and their associated pesticide resistance are captured through our research projects as well as through the WA grower and industry network via Pestfax Reporter and PestFax Map.

Useful and timely information is delivered to our clients through regular electronic newsletters such as PestFax, web-based disease risk forecasts, an SMS alert service, grains research update presentations, webpages, webinars, YouTube video and other media. Many of our field trials are located on Grower Group Field Day sites, allowing staff to directly showcase their research to consultants and growers. Annual training courses on integrated disease and insect pest management and identification are available to industry.