Your search keyword '"Veeragathipillai, Manoharan"' showing total 4 results

1. Impacts of a wildfire on soil organic carbon in Warrumbungle National Park, Australia

Author

Tulau, Mitch, Yang, Xihua, McAlpine, Robin, Veeragathipillai, Manoharan, Zhang, Mingxi, Karunaratne, Senani, Mcinnes-Clarke, Sally, and Young, Mark

Published

2020

2. Driving factors of soil organic carbon fractions over New South Wales, Australia

Author

Gray, Jonathan, Karunaratne, Senani, Bishop, Thomas, Wilson, Brian, and Veeragathipillai, Manoharan

Published

2019

3. Climatically driven change in soil carbon across a basalt landscape is restricted to non-agricultural land use systems

Author

Wilson, Brian R., King, Dacre, Crowns, Ivor, and Veeragathipillai, Manoharan

Subjects

Soil carbon -- Chemical properties -- Environmental aspects, Basalt -- Chemical properties -- Environmental aspects, Land use -- Environmental aspects, Agricultural industry, Earth sciences

Abstract

Soils represent a significant component of the global terrestrial carbon cyclc. Historical soil carbon depletion resulting from soil and land management offers an opportunity to store additional carbon to offset greenhouse gas emissions as part of our international response to climate change. However, our ability to reliably measure, estimate and predict soil carbon storage is hindered by a range of sources of variability, not least of which is change through time. In the present study, we assessed temporal changes in soil organic carbon (SOC) and its component fractions in response to climate alone and in the absence of land use change at any given site by examining a series of soil monitoring sites across a basalt landscape in north-west New South Wales under a range of land use types over a 3-year period (March-April 2008 and March-April 2011), where a significant rainfall event had occurred in the intervening time (2010). Across the dataset, woodland soils contained the largest carbon concentration (SOC%) and total organic carbon stock ([TOC.sub.s]) compared with other non-wooded land use systems, which themselves were statistically similar. However, larger carbon quantities were restricted largely to the surface (0-10 cm) soil layers. Between 2008 and 2011, significant increases in SOC% and [TOC.sub.s] were detected, but again these were restricted to the woodland sites. No change in particulate organic carbon (POC) was detected between the two sampling times, but both humic organic carbon (HOC) and resistant organic carbon (ROC) increased in woodland soils between the two sampling times. Increased HOC we attribute to microbial processing of soil carbon following the 2010-11 rainfall event. However, we suggest that increased ROC results from limitations in mid-infrared calibration datasets and estimations. We conclude that the quantity of soil carbon and its component fractions is, indeed, driven by climatic factors, but that these effects arc moderated by aboveground land use and SOC inputs. Received 4 August 2016, accepted 28 November 2016, published online 16 January 2017, Introduction Soils globally are estimated to contain approximately 1500 Gt carbon, which is more than is contained in vegetation and the atmosphere combined (Batjes 1996; Houghton 2005) and, as such, [...]

Published

2017

4. Differential growth and yield by canola (Brassica napus L.) and wheat (Triticum aestivum L.) arising from alterations in chemical properties of sandy soils due to additions of fly ash

Author

Isa A M, Yunusa, Veeragathipillai, Manoharan, Rob, Harris, Roy, Lawrie, Yash, Pal, Jonathan T, Quiton, Richard, Bell, and Derek, Eamus

Subjects

Crops, Agricultural, Plant Stems, Brassica napus, Industrial Waste, Western Australia, Hydrogen-Ion Concentration, Calcium Sulfate, Coal Ash, Models, Biological, Extraction and Processing Industry, Calcium Carbonate, Droughts, Trace Elements, Plant Leaves, Soil, Metals, Heavy, Seeds, New South Wales, Fertilizers, Triticum

Abstract

There is a need for field trials on testing agronomic potential of coal fly ash to engender routine use of this technology. Two field trials were undertaken with alkaline and acidic fly ashes supplied at between 3 and 6 Mg ha⁻¹ to acidic soils and sown to wheat and canola at Richmond (Eastern Australia) and to wheat only at Merredin (Western Australia).Ash addition marginally (P0.10) raised the pH in the top soil layers at both sites. The exceptionally dry season at both sites constrained yields and thwarted any likelihood of gaining yield benefits from ash-induced improvements in soil conditions. Yield improvements due to ash addition were absent at Merredin and only marginal at Richmond, where no elevated accumulation of B, Mo, Se, P or S in either the straw or seeds of wheat was observed; canola increased accumulation of Mo and Se in its shoot with acidic fly ash, but it was well below phyto toxic levels. Simulations of wheat using APSIM at Richmond over a 100-year period (1909-2008) predicted yield increases in 52% of years with addition of ash at 3.0 Mg ha⁻¹ compared with 24% of years with addition of ash at 6.0 Mg ha⁻¹. The simulated yield increases did not exceed 40% over the control with addition of 6 Mg ha⁻¹ ash, but was between 40% and 50% with an addition rate of 3 Mg ha⁻¹.We found no evidence of phytotoxicity in either crop in this unusually dry year and there is still a need for further field assessment in years with favourable rainfall to enable development of clear recommendations on fly ash rates for optimum yield benefits.

Published

2012