Carbon storage in relation to soil size-fractions under tropical tree-based land-use systems

Saha, Subhrajit; Nair, P. K. R.; Nair, Vimala D.; Kumar, B. Mohan

doi:10.1007/s11104-009-0123-x

Cited by 89 publications

(44 citation statements)

References 44 publications

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“…In general, the labile, resistant and aggregateassociated organic C fractions were also significantly correlated with each other, indicating that they were closely interrelated. On the other hand, our results indicated that the correlation coefficients were lower between SOC with labile C and macro-and micro-aggregate C than between SOC with resistant C and silt and clay sized C. It has been reported that silt and clay sized C was more stable than macro-and micro-aggregate C (Buyanovsky et al 1994;Six et al 2000;Saha et al 2010). Therefore, although labile C fractions have been suggested as early indicators of SOC changes (Haynes et al 2000), the resistant and stable C forms (i.e., humic C and silt and clay sized C) were the main determinant of SOC contents and stocks present in our study region.…”

Section: Soc and Its Fractionscontrasting

confidence: 47%

Soil organic carbon contents, aggregate stability, and humic acid composition in different alpine grasslands in Qinghai-Tibet Plateau

Cao

Yong

et al. 2016

J. Mt. Sci.

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Alpine grassland soils on Qinghai-Tibet Plateau store approximately 33.5 Pg of organic carbon (C) at 0-0.75 m depth and play an important role in the global carbon cycle. We investigated soil organic C (SOC), water-soluble organic C (WSOC), easily oxidizable organic C (EOC), humic C fractions, aggregate-associated C, aggregate stability, and humic acid (HA) composition along an east-west transect across Qinghai-Tibet Plateau, and explored their spatial patterns and controlling factors. The contents of SOC, WSOC, EOC, humic C fractions and aggregate-associated C, the proportions of macroaggregates (2-0.25) and micro-aggregates (0.25-0.053 mm), and the aggregate stability indices all increased in the order alpine desert < alpine steppe < alpine meadow. The alkyl C, O-alkyl C, and aliphatic C/aromatic C ratio of HA increased as alpine desert < alpine meadow < alpine steppe, and the trends were reverse for the aromatic C and HB/HI ratio. Mean annual precipitation and aboveground biomass were significantly correlated with the contents of SOC and its fractions, the proportions of macro-and microaggregates, and the aggregate stability indices along this transect. Among all these C fractions, SOC content and aggregate stability were more closely associated with humic C and silt and clay sized C in comparison with WSOC, EOC, and macro-and microaggregate C. The results suggested that alpine meadow soils containing higher SOC exhibited high soil aggregation and aggregate stability. Mean annual precipitation should be the main climate factor controlling the spatial patterns of SOC, soil aggregation, and aggregate stability in this region. The resistant and stable C fractions rather than labile C fractions are the major determinant of SOC stocks and aggregate stability. Keywords

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Section: Soc and Its Fractionscontrasting

confidence: 47%

Soil organic carbon contents, aggregate stability, and humic acid composition in different alpine grasslands in Qinghai-Tibet Plateau

Cao

Yong

et al. 2016

J. Mt. Sci.

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“…To the best of our knowledge, this study is the first to specifically address the effect of forest types on SOC stabilization through soil aggregation and soil physical fractions in a natural ecosystem. The very few studies focusing on this topic took place in managed plantation systems (e.g., Blanco-Canqui et al, 2007;Gama-Rodrigues et al, 2010;Quideau et al, 1998;Saha et al, 2010;Sarkhot et al, 2008), where soil disturbance is high and naturally-associated understory is generally lacking. In addition, the tree species selected in these studies were mostly genetically improved species [e.g., loblolly pine {Pinus taeda L.) and hybrid poplar clones].…”

Section: Discussionmentioning

confidence: 99%

Black Spruce Soils Accumulate More Uncomplexed Organic Matter than Aspen Soils

Laganière

Angers

Paré

et al. 2011

Soil Science Society of America Journal

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Improving knowledge on the dynamics and maintenance of the boreal soil's C pool is ot particular importance in response to climate change concerns. We hypothesized that different forest types (black spruce, trembling aspen, and mixedwood) found on a similar site type differentially affect soil organic carbon (SOC) distribution among physical fractions. The surface mineral soil (0-15 cm) of 24 plots differing in forest composition was sampled in forested Hapludalfe of the Abitibi-James Bay region, Canada. The soil was first separated into three water-stable aggregate size fractions (>1000, 1000-250, and <250 [un) by wet sieving, followed by a density flotation (Nal: 1.7 g cm"') and a dispersion (with glass beads) to isolate the free light fraction (LF), die intraa^regate partieulate organic matter (iPOM) and the silt plus clay fraction (S&C). According to mixed linear models, whole SOC contents (in Mg C ha"' ) decreased in the following order: black spruce (46.3) > mixedwood (41.9) > trembling aspen (34.7). While similar amounts of SOC (~30 MgC ha"') were found in the S&C, more SOC was found in the less protected fractions (i.e., uncomplexed organic matter, UOM : LF and iPOM) under black spruce than under trembling aspen, the mixedwood being intermediate. Tliis higher accumulation of UOM under black spruce suggests a slower C turnover that is probably induced by the low-quality C inputs and environmental constraints to decomposition found in these forests.These differences in the amounts of SOC stored within soil physical fractions might have strong repercussions on the SOC budget of the boreal forest of eastern Canada under dimate change.Abbreviations: CEC, cation exchange capacity; HF, heavy fraction; iPOM, intraaggregate partieulate organic matter Fraction; LF, light fraction; S&C, silt plus clay fraction; SOC, soil organic carbon; UOM, uncomplexed organic matter. B oreal soils hold one of the largest pools of terrestrial C in the form of SOC, storing around three times more SOC than temperate or tropical biomes (Lai, 2005). Accordingly, any variation in the size and turnover rate of this major C pool could alter atmospheric COj concentration and global climate.The residence time of C in soils is highly variable, ranging from a few days to thousands of years (von Lützow et al., 2006). Soil organic C stabilization and accumulation depend on a variety of factors, including C input rate and quality, and soil microclimatic conditions such as temperature and moisture that greatly affect the C output rate, that is, decomposition (Lorenz and Lai, 2010). Stabilization of SOC also occurs when organic matter and mineral particles are mixed together to form organo-mineral complexes. Tisdall and Oades (1982) conceptualized a hierarchical structure for soil aggregation that involves a distribution of organic matter into differently sized aggregates with varying degrees of stability.Interactions between organic matter, roots, microbes, and mineral particles generate macroaggregates (>250 [J^m) that contain C in various soil ...

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“…Our study indicated that medium surface cover with~40-50% gravel can provide optimal conditions for increasing SOC and TN stocks in the arid and windy regions. In addition, we did not study litter quality in this paper, but it is well known that the rate of litter decomposition and therefore the SOC content are dependent on plant litter quality, represented mainly by lignin and polyphenol contents and the nature and amount of root exudates (Saha et al, 2010;Xu et al, 2008).…”

Section: Discussionmentioning

confidence: 99%

“…Most previous studies have focused on the effect of vegetation type and management practices on soil carbon and nitrogen (e.g. Jelinski and Kucharik, 2009;Saha et al, 2010;Smith, 2008;Somaratne et al, 2005;Van Oost et al, 2007). Using gravel as a special mulch above the soil surface may have an important bearing on soil carbon sequestration in arid and semiarid regions by controlling wind erosion of soil, decreasing soil surface evaporation and changing soil physical behavior (Poesen and Lavee, 1994).…”

Section: Introductionmentioning

confidence: 99%

Effects of gravel on grassland soil carbon and nitrogen in the arid regions of the Tibetan Plateau

Wang¹,

Liu²,

Liu³

2011

Geoderma

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Carbon storage in relation to soil size-fractions under tropical tree-based land-use systems

Cited by 89 publications

References 44 publications

Soil organic carbon contents, aggregate stability, and humic acid composition in different alpine grasslands in Qinghai-Tibet Plateau

Soil organic carbon contents, aggregate stability, and humic acid composition in different alpine grasslands in Qinghai-Tibet Plateau

Black Spruce Soils Accumulate More Uncomplexed Organic Matter than Aspen Soils

Effects of gravel on grassland soil carbon and nitrogen in the arid regions of the Tibetan Plateau

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