Changes in soil carbon fractions due to incorporating corn residues in organic and conventional vegetable farming systems
Yadunath Bajgai A B E , Paul Kristiansen A , Nilantha Hulugalle C and Melinda McHenry DA School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia.
B RNR—Research and Development Centre Bajo, Department of Agriculture, Ministry of Agriculture and Forests, Wangdue Phodrang, Bhutan.
C NSW Department of Primary Industries, Narrabri, NSW 2390, Australia.
D Centre for Plant and Water Sciences, Central Queensland University, Bundaberg, Qld 4670, Australia.
E Corresponding author. Email: ybajgai@gmail.com
Soil Research 52(3) 244-252 https://doi.org/10.1071/SR13295
Submitted: 14 January 2013 Accepted: 6 January 2014 Published: 31 March 2014
Abstract
Vegetable production systems rely on frequent tillage to prepare beds and manage weeds, thereby accelerating losses of soil organic carbon (SOC). They are also characterised by scant crop residue input. Residue incorporation and organic fertiliser application could counteract SOC loss due to tillage. We tested this hypothesis in a Chromosol and a Vertosol in northern NSW, Australia, where the effects of incorporating sweet corn (Zea mays L. var. rugosa) residue in soil in a corn–cabbage (Brassica oleracea L.) rotation under either organic or conventional system on soil C fractions were studied during two rotation cycles (2 years). A laboratory experiment was conducted to isolate the effect of tillage on the soil organic matter (SOM) fractions, because both the residue-incorporated and without-residue treatments for organic systems received tillage for weed control in the field, whereas conventional systems did not. Residue incorporation increased particulate OC (POC) by 32% in the field experiment and 48% in the laboratory experiment, whereas dissolved OC was increased only in the organic system. Concentrations of mineral-associated OC (MOC) and total OC (TOC) were increased by residue incorporation in both field and laboratory experiments. Simulated tillage had a limited effect on POC, MOC and TOC, suggesting that cultivation for weed control may have only a minor effect on short-term SOM mineralisation rates. In both experiments, MOC accounted for ≥83% in the Vertosol and ≥73% in the Chromosol. Due to frequent tillage in vegetable production systems, physicochemical stabilisation of C predominates over protection through aggregation.
Additional keywords: dissolved organic carbon, mineral-associated OC, particulate OC, residue management, total OC.
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