The effect of soil texture and roots on the stable carbon isotope composition of soil organic carbon

Bird, Michael I.; Kracht, Oliver; Derrien, Delphine; Zhou, Youcai

doi:10.1071/sr02044

Cited by 81 publications

(58 citation statements)

References 52 publications

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“…These results are consistent with those reported by other authors, e.g. Nadelhoffer and Fry (1988), Accoe et al (2003) and Bird et al (2003). The results of a litter bag experiment led Connin et al (2001) to suggest that mechanisms responsible for isotopic discrimination are, at least partly, characteristic of earlier decay stages.…”

Section: And N Distribution In Som Fractionssupporting

confidence: 94%

Anthropogenic disturbance of natural forest vegetation on calcareous soils alters soil organic matter composition and natural abundance of 13C and 15N in density fractions

2010

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In the last century, many calcareous soils in Castilla León (northwestern Spain) have been transformed from natural Quercus ilex forest to cropped land. Reforestation with Pinus halepensis has been taking place during the past 40 years. In order to obtain a better understanding of how these disturbances affect ecosystem functioning, we studied the quantity and quality of soil organic matter (SOM) in natural forest ecosystems, cropland and Pinus plantations. Density fractionation combined with ultrasonic dispersion enables separation and study of SOM fractions: free organic matter (OM), OM occluded into aggregates and OM stabilized in organo-mineral complexes, considered on the basis of the type of physical protection provided. We separated SOM density fractions and determined the concentrations of C and N, C/N ratios and the natural isotopic abundance (d 13 C and d 15 N values). Transformation of Quercus forest to cropland resulted in major losses of SOC and N, as expected. However, subsequent reforestation with Pinus resulted in good recovery of the original SOC and soil N pools. This indicates the potential for enhanced C storage in agricultural soils by their reversion to a forested state. Study of the density fractions and their 13 C and 15 N signatures enabled better understanding of the high stability of OM in calcareous soils, and analysis of d 13 C variations throughout the profile also enabled identification of past C3/C4 vegetation change. Despite the different OC contents of soils under different land use, OM stabilization mechanisms were not significantly different. In calcareous soils, accumulation of SOC and N is mainly due to organo-mineral associations, resulting in physicochemical stabilization against further decomposition.

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Section: And N Distribution In Som Fractionssupporting

confidence: 94%

Anthropogenic disturbance of natural forest vegetation on calcareous soils alters soil organic matter composition and natural abundance of 13C and 15N in density fractions

2010

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“…By contrast, in samples with smaller SSA, which presumably contain less protective mineral phases, HF treatment released predominantly 13 C-depleted organic constituents. This finding agrees with the view that potentially biodegradable compounds enriched in 13 C such as polysaccharides and proteins can be stabilized by mineral surfaces (Bird et al 2003;Kiem and Ko¨gel-Knabner 2003) and are thus effectively removed during mineral dissolution (Dai and Johnson 1999;Schmidt and Gleixner 2005).…”

Section: Mineral-protected Organic Mattersupporting

confidence: 89%

Stabilization of Soil Organic Matter: Association with Minerals or Chemical Recalcitrance?

et al. 2006

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Soil organic matter (OM) can be stabilized against decomposition by association with minerals, by its inherent recalcitrance and by occlusion in aggregates. However, the relative contribution of these factors to OM stabilization is yet unknown. We analyzed pool size and isotopic composition ( 14 C, 13 C) of mineral-protected and recalcitrant OM in 12 subsurface horizons from 10 acidic forest soils. The results were related to properties of the mineral phase and to OM composition as revealed by CPMAS 13 C-NMR and CuO oxidation. Stable OM was defined as that material which survived treatment of soils with 6 wt% sodium hypochlorite (NaOCl). Mineral-protected OM was extracted by subsequent dissolution of minerals by 10% hydrofluoric acid (HF). Organic matter resistant against NaOCl and insoluble in HF was considered as recalcitrant OM. Hypochlorite removed primarily 14 C-modern OM. Of the stable organic carbon (OC), amounting to 2.4-20.6 g kg À1 soil, mineral dissolution released on average 73%. Poorly crystalline Fe and Al phases (Fe o , Al o ) and crystalline Fe oxides (Fe dÀo ) explained 86% of the variability of mineral-protected OC. Atomic C p /(Fe+Al) p ratios of 1.3-6.5 suggest that a portion of stable OM was associated with polymeric Fe and Al species. Recalcitrant OC (0.4-6.5 g kg À1 soil) contributed on average 27% to stable OC and the amount was not correlated with any mineralogical property. Recalcitrant OC had lower D 14 C and d 13 C values than mineral-protected OC and was mainly composed of aliphatic (56%) and O-alkyl (13%) C moieties. Lignin phenols were only present in small amounts in either mineral-protected or recalcitrant OM (mean 4.3 and 0.2 g kg À1 OC). The results confirm that stabilization of OM by interaction with poorly crystalline minerals and polymeric metal species is the most important mechanism for preservation of OM in these acid subsoil horizons.Abbreviations: CPMAS 13 C-NMR -cross-polarization magic-angle spinning 13 C nuclear magnetic resonance spectroscopy; FR -fluoride reactivity; OC -organic C; OM -organic matter; MOC and MN -mineral-protected organic C and N; ROC and RN -chemically resistant (recalcitrant) organic C and N; SSA -specific surface area; XRD -x-ray diffraction; TEM -transmission electron microscopy

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“…This would lead to depletion of δ 13 C in soil organic matter relative to the starting litter inputs, at least in the early stages (e.g., Flanagan et al 1999;Garten et al 2000;Quideau et al 2003). However, numerous studies (e.g., Buchmann et al 1997;Flanagan et al 1999;Ehleringer et al 2000;Feng 2002;Bird et al 2003;Quideau et al 2003) have shown that decomposition of organic matter is associated with increasing δ 13 C. The δ 13 C value usually increases with soil depth or with decreasing particle-size fraction within a depth range, as soil organic matter becomes increasingly dominated by microbial necromass stabilized by mineral association (Bird et al 2003).…”

mentioning

confidence: 99%

Decomposition, δ¹³C, and the “lignin paradox”

Preston¹,

Trofymow²,

Flanagan³

2006

Can. J. Soil. Sci.

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. 2006. Decomposition, ␦ 13 C, and the "lignin paradox". Can. J. Soil Sci. 86: 235-245. The natural abundance of 13 C (δ 13 C) generally increases with decomposition of organic matter. This is contrary to the expected decrease, as lignin is hypothesized to accumulate relative to isotopically heavier cellulose. Our objective was to test the hypothesis that 13 C depletion should be observed for gymnosperm logs that typically develop advanced brown-rot decay with high lignin content. With increasing lignin concentration [previously determined by nuclear magnetic resonance (NMR)], δ 13 C tended to become more negative for samples of Pseudotsuga menziesii, Tsuga heterophylla, Thuja plicata, and unidentified species from Coastal Forest Chronosequence sites of southern Vancouver Island. For a larger sample set without NMR analysis, δ 13 C was significantly more depleted for the highest decay classes, and total C was negatively correlated with δ 13 C, consistent with the higher total C of lignin than of cellulose. Relationships of total C and δ 13 C with density were much weaker. We discuss causes for the variability of δ 13 C in coarse woody debris from these sites, and how the apparent paradox in the predicted change of δ 13 C with decomposition is largely due to the confusion of lignin, the biopolymer produced by higher plants, with the acid-unhydrolyzable residue (AUR) of the proximate analysis procedure commonly used to assess litter quality in decomposition studies. J. Soil Sci. 86: 235-245. La quantité de 13 C (δ 13 C) présente dans la nature augmente généralement avec la décomposition de la matière organique. Cette constatation contredit la baisse de concentration prévue, l'hypothèse étant que c'est la lignine qui devrait s'accumuler au lieu de l'isotope plus lourd de la cellulose. Les auteurs voulaient savoir si le 13 C s'épuise vraiment dans les grumes de gymnospermes qui donnent habituellement une pourriture brune riche en lignine. Avec la hausse de la concentration de lignine (déter-minée au préalable par RMN), la teneur en δ 13 C a tendance à devenir négative dans les échantillons de Pseudotsuga menziesii, Tsuga heterophylla, Thuja plicata et des espèces non identifiées venant des chronoséquences de la forêt côtière du sud de l'île Vancouver. Dans une série d'échantillons plus importante n'ayant pas été analysés par RMN, la concentration de δ 13 C était significativement plus faible dans les spécimens à décomposition la plus avancée, et la concentration totale de carbone présentait une corrélation négative avec l'isotope δ 13 C, confirmant la concentration supérieure de carbone issu de la lignine plutôt que de la cellulose. Les liens entre la concentration totale de carbone et celle de δ 13 C avec la densité sont nettement plus ténus. Les auteurs parlent des causes de la variabilité de la concentration de δ 13 C dans les débris ligneux grossiers prélevés aux différents sites et du paradoxe apparent quant à l'évo-lution de la teneur en δ 13 C attribuable à la décomposition. Ce paradoxe résulte, selon eux, d'...

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The effect of soil texture and roots on the stable carbon isotope composition of soil organic carbon

Cited by 81 publications

References 52 publications

Anthropogenic disturbance of natural forest vegetation on calcareous soils alters soil organic matter composition and natural abundance of 13C and 15N in density fractions

Anthropogenic disturbance of natural forest vegetation on calcareous soils alters soil organic matter composition and natural abundance of 13C and 15N in density fractions

Stabilization of Soil Organic Matter: Association with Minerals or Chemical Recalcitrance?

Decomposition, δ¹³C, and the “lignin paradox”

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The effect of soil texture and roots on the stable carbon isotope composition of soil organic carbon

Cited by 81 publications

References 52 publications

Anthropogenic disturbance of natural forest vegetation on calcareous soils alters soil organic matter composition and natural abundance of 13C and 15N in density fractions

Anthropogenic disturbance of natural forest vegetation on calcareous soils alters soil organic matter composition and natural abundance of 13C and 15N in density fractions

Stabilization of Soil Organic Matter: Association with Minerals or Chemical Recalcitrance?

Decomposition, δ13C, and the “lignin paradox”

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Decomposition, δ¹³C, and the “lignin paradox”