sg:pub.10.1007/s11368-010-0279-2 - Springer Nature SciGraph

Article Info

DATE

2010-08-13

AUTHORS

Chitdeshwari Thiyagarajan, Richard W. Bell, Jonathan D. Anderson, Ian Phillips

ABSTRACT

PurposeRe-vegetation is the preferred long-term practice for managing Alcoa’s bauxite-processing residue storage areas. Residue sand is the primary growth medium for rehabilitation; however, it is largely nutrient deficient. Although addition of organic and inorganic amendments can provide short-term supply of plant-available nutrients, but quickly exhausted, thus long-term deficiencies are often observed. The rapid transformation of added zinc into non-available pools is predicted as the main factor limiting vegetation performance.Materials and methodsTwo laboratory investigations were carried out to assess the effect of organic (composts) and inorganic (various types of red mud) amendments on Zn availability in residue sand. Three compost mixtures (piggery, biosolid and commercial compost), three rates of application (0, 10 and 50 t ha−1) were taken as organic amendments and incubated with residue sand for 30 days to examine the effects of compost on Zn availability. Seven column treatments were set up as: control residue sand, homogeneous mixtures of residue sand with 3% (w/w) and 8% (w/w) seawater-washed, carbonated or unaltered red mud with residue sand. Leaching with distilled water was carried out every 3 days by adding 1/6th pore volume and analysed for Zn availability and its distribution in various chemical pools.Results and discussionFractionation studies found that Zn availability decreased with incubation time and red mud amendments. Residue pH and organic C were the major factors controlling Zn availability and its distribution. Column studies showed limited Zn mobility in residue sand even after three pore volumes of drainage. Increased DTPA extractable Zn in surface layers of residue sand with and without red mud amendments after leaching was found and attributed to decrease in residue water-soluble alkalinity. Addition of commercial compost (50 t ha−1) increased DTPA Zn, decreased the alkalinity and increased C content in residue sand. The red mud amendments had contrasting effects on Zn that were related to pH of the materials. Addition of seawater-washed red mud increased DTPA Zn in residue sand whereas unaltered red mud decreased DTPA Zn.ConclusionsPlant available Zn extracted with 50 t ha−1 of commercial composts addition was well above deficient range, suggesting that they could be an effective Zn source for vegetation establishment. Zinc occurred predominantly in organically bound form in compost-amended sand and as carbonate-bound form in leached red mud-amended columns, but the longer term effects of these Zn forms on the release of Zn for plant growth remain unclear. More... »

PAGES

101-114

References to SciGraph publications

1993. Diagnosis of Zinc Deficiency in ZINC IN SOILS AND PLANTS

2005-06. Reclamation of Fine Fraction Bauxite Processing Residue (Red Mud) Amended with Coarse Fraction Residue and Gypsum in WATER, AIR, & SOIL POLLUTION

<error retrieving object. in <ERROR RETRIEVING OBJECT

2005-01. Nutrient status of vegetation grown in alkaline bauxite processing residue amended with gypsum and thermally dried sewage sludge - A two year field study in PLANT AND SOIL

2003-11. Deep placement of manganese fertiliser improves sustainability of lucerne growing on bauxite residue: A glasshouse study in PLANT AND SOIL

2001-07. Bauxite residue sand has the capacity to rapidly decrease availability of added manganese in PLANT AND SOIL

2006-03-03. Effective Nutrient Sources for Plant Growth on Bauxite Residue in WATER, AIR, & SOIL POLLUTION

Journal

TITLE

Journal of Soils and Sediments

ISSUE

VOLUME

Subjects

FOR: Earth Sciences

FOR: Environmental Sciences

FOR: Agricultural And Veterinary Sciences

Author Affiliations

Department of Soil Science and Agricultural Chemistry, TamilNadu Agricultural University, 641 003, Coimbatore, TamilNadu, India

School of Environmental Science, Murdoch University, 6150, Murdoch, WA, Australia

Mining Environmental, Alcoa of Australia, P.O. Box 172, 6208, Pinjarra, WA, Australia

Identifiers

URI

http://scigraph.springernature.com/pub.10.1007/s11368-010-0279-2

DOI

http://dx.doi.org/10.1007/s11368-010-0279-2

DIMENSIONS

https://app.dimensions.ai/details/publication/pub.1009015620

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