US EPA

4171948 

Journal Article 

Organic carbon characteristics in density fractions of soils with contrasting mineralogies 

Yeasmin, S; Singh, B; Johnston, CT; Sparks, DL 

2017 

Yes 

Geochimica et Cosmochimica Acta
ISSN: 0016-7037 

218 

215-236 

10.1016/j.gca.2017.09.007 

WOS:000412998300012 

This study was aimed to evaluate the role of minerals in the preservation of organic carbon (OC) in different soil types. Sequential density fractionation was done to isolate particulate organic matter (POM, < 1.8 g cm(-3)) and mineral associated OM (MOM: 1.8-2.2, 2.2-2.6 and > 2.6 g cm(-3)) from four soils, i.e., a Ferralsol, a Luvisol, a Vertisol and a Solonetz. Organic matter (OM) in the density fractions was characterised using diffuse reflectance Fourier transform infrared spectroscopy, X-ray photoelectron spectroscopy and mass spectroscopy in the original states (i.e., without any chemical pre-treatment), and after 6% sodium hypochlorite (NaOCl) and 10% hydrofluoric acid (HF) treatments. The NaOCl oxidation resistant fraction was considered as a relatively stable pool of OC and the HF soluble fraction was presumed as the mineral bound OC. Phyllosilicate-dominated soils, i.e., Vertisol, Luvisol and Solonetz, contained a greater proportion of POM than Fe and Al oxide-dominated Ferralsol. Wider C:N ratio and lower delta C-13 and delta N-15 in POM suggest the dominance of labile OC in this fraction and this was also supported by a greater proportion of NaOCl oxidised OC in the same fraction that was enriched with aliphatic C. The sequential density fractionation method effectively isolated OM into three distinct groups in the soils: (i) OM associated with Fe and Al oxides (> 1.8 g cm(-3) in the Ferralsol); (ii) OM associated with phyllosilicates (1.8-2.6 g cm(-3)) and (iii) OM associated with quartz and feldspar (> 2.6 g cm(-3)) in the other three soils. Greater oxidation resistance, and more dissolution of OC during the HF treatment in the Fe and Al oxides dominated fractions suggest a greater potential of these minerals to protect OC from oxidative degradation as compared to the phyllosilicates, and quartz and feldspar matrices. OM associated with Fe and Al oxides was predominantly aromatic and carboxylate C. Decreased C: N ratio in the NaOCl oxidation resistant OM and HF soluble OM of phyllosilicates, and quartz and feldspars dominant fractions compared to their untreated fractions indicate a preferred retention of N rich organic compounds by these minerals. OM associated with phyllosilicates was enriched with protonated amide N and aromatic C. Quartz and feldspars associated OM comprised of N containing organic compounds and polysaccharides, although we don't expect any role of these minerals in their preservation. Our results imply that the abundance and surface properties of minerals in the soil largely control the dynamics of OC and subsequently protect OC from microbial cycling. (C) 2017 Elsevier Ltd. All rights reserved. 

Soil organic carbon; Sodium hypochloride oxidation; Hydrofluoric acid treatment; Particulate organic matter; Mineral-associated organic matter; Infrared spectroscopy