Soil health and nutrient management
Permanent URI for this collectionhttp://elibrary2.sugarresearch.com.au/handle/11079/13842
Research outcomes: Soil health is improved with a resulting positive impact on the environment and yield growth. Improved reputation and relationship between industry and environmental groups.
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Item Effect of long-term application of potassium on sugarcane and soil properties in the Herbert River district : ASSCT peer-reviewed paper(ASSCT, 2019) Park, G; Schroeder, BL; Wood, AW; Skocaj, DMExcess potassium (K) fertiliser use can have a significant effect on sugar quality and refining costs but offers no benefit to sugarcane crop yield. Potassium fertiliser guidelines are based on soil texture and two measures of soil potassium: readily available or exchangeable K and reserve K. The maximum recommended K rate for the Herbert is 120 kg/ha. A long-term K trial was established on a sandy loam soil at Macknade. High K application rates increased soil exchangeable K levels and resulted in luxury K consumption by the sugarcane plant. This significantly increased juice conductivity and third-leaf K levels. It also resulted in significant reductions in third-leaf values for Ca and Mg.Item Improving the efficiency of nitrogen fertilisation of sugarcane under minimum till and trash conservation cultural conditions (Final report SRDC Project BS37S)(1992) Chapman, LS; Freney, R; Denmead, OT; Wood, AW; Saffigna, PGObjectives of the experiments were (1) Determine the extent of NH3 volatilisation when urea and ammonium sulfate are applied to the surface of a trash blanket in four cane-growing regions. Evaluate the effect of various placements of urea in a trash blanket under wet and dry moisture regimes by quantifying the amount of N recovered in the soil-plant system.Item A reference booklet for canegrowers on the nutrition and fertilizing of sugarcane for different soil types(2003) Wood, AW; Schroeder, BL; Stewart, RL; Roth, CHA wide range of different soils are used for sugarcane production in the Herbert River district. An understanding of these differences both at district and farm levels will ensure that nutrient management reflects this diversity and enables profitable and sustainable sugarcane production. The Australian sugar industry has used a generalised, industry-wide set of fertiliser recommendations with no specific guidelines for different regions, climatic conditions or soil types. This booklet is a first attempt to produce specific management guidelines for all of the different soil types used for sugarcane production in a cane area. Twenty four different soil types have been identified in the sugarcane production area of the Herbert and have been mapped at a scale of 1:5000, which is appropriate for soil-specific management recommendations to be delivered at block level. Growers can currently access soil maps of their farms through Herbert Cane productivity Services Ltd. and plans are in place to provide all growers with the capability of printing their own soil maps. In the booklet each soil type is described in terms of its appearance, where it occurs in the landscape, and its chemical and physical properties. Guidelines for the management of nutrients, tillage, drainage and irrigation and the minimisation of environmental risks are provided for each soil type. These guidelines have been developed using research results from a companion SRDC funded project, BSS232 “Improved nutrient management in the Australian Sugar Industry”. The soil booklet produced in this project is likely to be the first of a number of regional soil management publications that are likely to be produced for the Australian Sugar Industry. The booklet is intended for use by cane growers and their advisers, and where possible the information is presented in as non-technical way as possible. This approach is particularly appropriate for the current situation of the sugar industry with continuing low sugar prices, the need to reduce production costs together with mounting environmental pressures which demand demonstration of responsible soil and nutrient management. The guidelines in this booklet are aimed at providing best practice soil and nutrient management for Herbert growers that will not only maintain or improve crop yields and soil fertility but will also provide opportunities for cost reduction whilst enhancing sustainability and delivering better environmental outcomes.Item Final report SRDC Project CSR024 Improving the environment for sugarcane growth through the amelioration of soil acidity(2002) Wood, AW; Noble, AD; Bramley, RGVMost soils used for growing sugarcane in wet tropical northern Queensland are highly acidic. Comparisons between new cane land and land that has been growing sugarcane for many years have demonstrated that our soils have become degraded under continuous sugarcane monoculture and that many of the changes in soil chemical properties are associated with soil acidification. Continued acidification, due to heavy applications of nitrogen fertilizer and the removal of base cations in the cane sent to the mill, will not only further acidify surface soils but will also progressively acidify the lower parts of the soil profile, making amelioration difficult and costly. Low soil pH not only reduces the availability of some nutrients to plants but also reduces soil surface charge resulting in a permanent reduction in the capacity of the soil to hold nutrients. Since many soils in the wet tropics already have a low cation exchange capacity, further reductions in cation exchange capacity (CEC) due to accelerated acidification may lead to sub-optimal levels of exchangeable calcium, magnesium and potassium, which will have a direct impact on sugarcane yields. Current industry recommendations for applying lime are based on perceived economic crop responses to calcium and are based only on the level of soil exchangeable calcium in the surface layer. Whilst this philosophy may be appropriate for soils with very low cation exchange capacities and suboptimal levels of exchangeable calcium, where frequent lime applications would be required to maintain soil calcium levels, it does not offer a sustainable management solution for highly acidic soils with adequate exchangeable calcium levels. Over 85% of cane growing soils in the Herbert River District fall into this category, having exchangeable calcium levels above the critical level and yet having an average soil pH of less than 5. This project aims to enhance the sustainability of the sugar industry by investigating and developing strategies for ameliorating soil acidity and thus making soils more amenable not only for sugarcane production but also for leguminous fallow crops which are now considered to be an important part of a sustainable sugarcane production system. Replicated experimental trials involving five rates of lime and three rates of gypsum were established on farms in the Herbert River District with contrasting soils that were highly acidic but had exchangeable calcium above the critical level. A fourth trial site was included later in the project with very low exchangeable calcium levels. Cane yields and ccs were monitored and soil samples taken from different depths in selected treatments in each trial were analysed in order to monitor changes in soil chemical properties.Item Risk assessment of phosphorus (P) loss and guidelines for P use in lower Herbert soils Final report on SRDC Project No CLW010(2000) Bramley, RGV; Wood, AWIn project CSS3S (Bramley et aI., 1998), a field and laboratory-based survey of the behaviour of phosphorus (P) was carried out on the soils of the lower Herbert River catchment, and sediments derived from them. The aim was to explore the factors governing P sorption or desorption in Herbert soils, and in suspended sediments in associated riverine and estuarine waters, so that the extent of any problem associated with sugarcane and soil-derived inputs to strearnwaters could be defined and advice on the development of best management practices for P fertilizer could be provided. Accordingly, an assessment of the risk of P loss from selected lower Herbert soils was made based on their P sorption characteristics and an assessment of the susceptibility of the lower Herbert soils to runoff following rainfall events. One of the recommendations made at the conclusion of CSS3S was that "spatial analysis of the assessment of P desorption risk based on digital maps of the CSR soil survey would enable more precise guidelines for better P management to be derived.". Following the recent availability of the CSR 1:5,000 soil survey in geo-referenced digital form, this report details the results of the suggested spatial analysis. Nine hundred and thirty four soils for which detailed soil property data are available in the database accompanying the 1:5,000 CSR survey of lower Herbert sugarcane soils were classified according to a range of indices of P sorption and the results mapped using either a geostatistical interpolation routine (kriging) or the mean values for each soil type identified in field survey. The results were coupled with an analysis of the susceptibility of these soils to runoff to produce maps of the potential for P loss.Item Environmentally sound phosphorus management for sugarcane soils : final report on SRDC Project no CSS3S(1998) Bramley, RGV; Edis, RB; White, RE; Wood, AWA field and laboratory-based survey of the behaviour of phosphorus (P) was carried out on the soils of the lower Herbert River catchment, and sediments derived from them. The aim was to explore the factors governing P sorption or desorption in Herbert soils, and in suspended sediments in associated riverine and estuarine waters, so that the extent of any problem associated with sugarcane and soil-derived inputs to streamwaters could be defined. With this information, advice on the development of best management practices for P fertilizer could be provided to the sugar industry. The results of the study of P behaviour in Herbert soils suggests that there is scope for refining the management of P fertilizer in the sugar industry based on a knowledge of particular soil properties and the behaviour of P in specific soils. Sorption of P in soils was found to be closely correlated with soil particle size, organic matter content and oxalate-extractable aluminium (Al). The results of this part of the project suggest that: • in refining P fertilizer management, both for more efficient crop production and improvec\ environmental stewardship, the utility of oxalate-extractable aluminium (Alo,) as a predictor of P fertilizer requirement should be investigated; and • clustering soils with similar physical and chemical properties is useful as a basis for identifying soils of similar potential P sorption/desorption characteristics so that, when coupled with a knowledge of the soil P content measured using normal soil testing procedures, they may' also form a basis for delivery of improved fe~tilizer advice. Further research is therefore warranted on both of these issues with a view to the developme!1t of specific guidelines for best-practice P fertilizer management.Item Improving the management of acid and sodic soils with green trash retention using calcium-based ameliorants/products : SRDC final project report BSS199(2003) Schroeder, BL; Noble, AD; Robertson, FA; Nelson, PN; Wood, AWAlthough the advantages of leaving cane residues on the harvested land have been well documented, and nutrient cycling in relation to green-cane trash blanketing has been well examined within a Cooperative Research Centre for Sustainable Sugar Production (CRC Sugar) program activity, little work has been done to investigate the effects of trash management on soil chemical properties and the ameliorative advantages of applying Ca-containing amendments to crop residues. As lime, lime/gypsum applications are generally used to ameliorate acid soil conditions, a Ca-source followed by leaching is the principal strategy for managing sodic soils, and mill by-products (mill mud and mill ash) are often applied to plant cane, it was considered pertinent to investigate the effects of these and other amendments on the decomposition of trash on sugar industry soils.This project aimed at quantifying the effects of trash retention on soils acidity, examining the efficacy of Ca-containing amendments and trash for ameliorating sodic soils, assessing the effect of Ca-based amendments on trash decomposition and nutrient availability, and quantifying trash decomposition and C and N relationships. To do this, the project comprised four distinct but interlinked facets and included a series of laboratory investigations, glasshouse experiments and a field trial.