Relationship between soil clay mineralogy and carbon protection capacity as influenced by temperature and moisture

Singh, Mandeep; Sarkar, Binoy; Biswas, Bhabananda; Bolan, Nanthi S.; Churchman, Gordon Jock

Title: Relationship between soil clay mineralogy and carbon protection capacity as influenced by temperature and moisture
Creator: Singh, Mandeep; Sarkar, Binoy; Biswas, Bhabananda; Bolan, Nanthi S.; Churchman, Gordon Jock
Relation: ARC.DP140100323 http://purl.org/au-research/grants/arc/DP140100323
Relation: Soil Biology and Biochemistry Vol. 109, Issue June 2017, p. 95-106
Publisher Link: http://dx.doi.org/10.1016/j.soilbio.2017.02.003
Publisher: Pergamon Press
Resource Type: journal article
Date: 2017
Description: Environmental conditions like temperature and moisture could affect the carbon protection capacity of various clay types in soils. Using dominantly kaolinitic-illitic, smectitic and allophanic soils, we conducted systematic incubation experiments over 42 days at different temperatures (4, 22 and 37 °C) and moisture contents (30, 60 and 90% of water holding capacity (available water)). The basal respiration was monitored to study the relative effect of moisture contents and temperature on the carbon protection capacities and mechanisms of the three clay types. The results indicated that carbon decomposition increased with increasing moisture and temperature. A two-component quadratic equation could explain the carbon mineralisation process. The highest C respiration was observed at 37 °C with a 60% moisture level in each of the soil types. Under these conditions, the smectitic soil recorded the highest carbon decomposition followed by the kaolinitic-illitic and allophanic soils. The study of the priming effect using ¹⁴C labelled malic acid confirmed the trend of the bulk respiration results. The allophanic soil showed the lowest amount of carbon mineralisation under all experimental conditions. A strong inverse correlation (R² = 0.90 at p < 0.05) was observed between CO₂ emission rate and total sesquioxides (Fe and Al oxides) content. As evidenced by the pore size distribution, micromorphologies and thermogravimetric analyses, the microporous structure and microaggregate formation in the allophanic soil enhanced carbon sequestration. This study indicated that soil carbon stabilisation was related more to the sesquioxides content than to the clay types or their relative specific surface areas
Subject: soil carbon mineralisation; cay minerals; Fe and Al oxides; porous structure; priming effect; thermogravimetric analysis
Identifier: http://hdl.handle.net/1959.13/1354888
Identifier: uon:31377
Identifier: ISSN:0038-0717
Language: eng
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