Labile forms of carbon and soil aggregates

Tobiašová, Erika; Barančíková, Gabriela; Gömöryová, Erika; Makovníková, Jarmila; Skalský, Rastislav; Halas, J.; Koco, Štefan; Tarasovičová, Zuzana; Takáč, Jozef; Špaňo, M.

doi:10.17221/182/2015-swr

Cited by 10 publications

(10 citation statements)

References 23 publications

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“…Therefore, stable MaAs would also contain some additional organic matter (Figure 6d). Tobiašová et al [35] indicated the similar outcomes with our results by evaluating LOC (WEOC and ROC) in the aggregate with different sizes. Based on our results, the RSOC seems to be transformed into MBC fraction obviously in MaAs and MeAs, 2021, 9, 1431 which implied that the susceptible fresh OM might be occluded during formation process of larger aggregates.…”

Section: Effects Of Biochar On the Formation Of Soil Aggregatessupporting

confidence: 90%

Effects of Biochar on Soil Aggregation and Distribution of Organic Carbon Fractions in Aggregates

et al. 2021

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Soil aggregates are among crucial factors for determining both the quality and erosion resistance of soils. Biochar is a soil amendment that has seen increasing use to improve specific soil properties, mainly the physical structure and the preserving capacity of water and nutrients, as well as sequestration of soil organic carbon. In this study, we applied the rice husk biochar (RHB) and cattle manure compost (COM) in a sandy loam rural soil, which is widely distributed in southern Taiwan, to investigate the combined effects of the biochar and compost on soil aggregation and dynamic change of organic carbon fractions. Through our incubation experiment, both biochar and compost could promote the soil aggregation after eight weeks incubation. The total amounts of macroaggregates (MaAs, >2.0 mm) and mesoaggregates (MeAs, 0.25–2.0 mm) increased by 1.3–9%. During aggregation processes, a considerably greater amount of the soil organic carbon was found to enrich mainly in MaAs and MeAs in all treatments. The COM addition in the soil further promotes organic carbon enrichment in microaggregates (MiAs, <0.25 mm) + fine particles and MeAs after incubation. Increasing labile organic C (LOC) fractions were significantly found in MaAs and MeAs during aggregation processes, whereas decreasing LOC fractions were found in MiAs. The input of fresh organic matter (RHB and COM) initial acts as binding agents in MiAs, and then further enhances the formation of MeAs and MaAs gradually. In conclusion, RHB promotes the physical protection of organic C by increasing soil aggregation and is hence a management option to enhance the C sequestration potential.

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Section: Effects Of Biochar On the Formation Of Soil Aggregatessupporting

confidence: 90%

Effects of Biochar on Soil Aggregation and Distribution of Organic Carbon Fractions in Aggregates

et al. 2021

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“…These increases in HWC, microbial biomass and respiration potential were correlated to the soil organic matter content, which was 37% higher under Eucalyptus compared to potato and fallow land uses (Coca-Salazar et al 2021a). Moreover, the absence of soil physical perturbation (Eucalyptus soils are not managed after seedling plantation) could also favour the formation of new aggregates and the binding of the already existing free macroaggregates, microaggregates and silt + clay (Tisdall and Oades 1982;Tobiašová et al 2016). The observed higher soil aggregate stability in water under Eucalyptus is also generally explained by higher soil C content (Wei et al 2006) and a more active microbial community, which is considered to be the consequence of successful afforestation (Caravaca et al 2002).…”

Section: Land Use Effects On Soil Aggregates Toc Tn Concentrations An...mentioning

confidence: 99%

“…Understanding the link between soil C, microorganisms and soil aggregates under different land uses is essential to shed light on the consequences of modifications in soil structure for soil organic matter dynamics and the potential resulting effects on nutrient availability and biogeochemical cycles. Indeed, increased relative abundance of mega-and macroaggregates indicate higher labile carbon content, soil porosity, oxygen diffusion, water infiltration, root penetration and decreased risk of erosion (Whalen and Chang 2002;Pagliai et al 2004;Tobiašová et al 2016). Higher abundance of mega-and macroaggregates is thus generally linked to increased rates of biological processes and higher nutrient availability (Cai et al 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Different land uses strongly influence both soil organic C and microbial activity (Li et al 2020;Vazquez et al 2020). For example, in agricultural land uses, tillage may lead to the breakdown of macro-and megaaggregates (Whalen and Chang 2002;Tobiašová et al 2016), and increased decomposition, leading to a depletion of labile C with a subsequent decrease in microbial biomass and microbial activity (e.g. C respiration and N mineralisation).…”

Section: Introductionmentioning

confidence: 99%

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Soil microbial biomass and oxy-hydroxides contribute to aggregate stability and size distribution under different land uses in the Central Andes

2022

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Context Agricultural intensification leads to land use changes with potential consequences for soil aggregate stability and size distribution, affecting nutrient and water retention capacity, aeration, sequestration of soil organic carbon, and biogeochemical cycling. Aims This study evaluated soil aggregate stability and size distribution under potato, fallow and Eucalyptus globulus L. land uses in Cambisols of the eastern branch of the Central Andes, Bolivia. We also investigated the relation between aggregates and total C, extractable C, oxy-hydroxides, microbial biomass and activity. Methods Aggregate stability, size distribution and oxy-hydroxides were measured in soil samples from eight plots of each land use. Key results Compared to fields cultivated with potato (Solanum tuberosum L.), Eucalyptus increased aggregate stability, megaaggregate content, and C and N in the free silt + clay fraction. Fallow did not lead to significant changes in soil structure. Soil aggregate stability was related to both microbial biomass and oxy-hydroxides. Microbial biomass C, microbial activity and dithionite extractable Fe were positively related to megaaggregates and aggregate stability. Oxalate extractable Fe and Mn were related to microaggregates. Conclusions The plantation of Eucalyptus is suitable for soil structural amelioration and C sequestration, but its introduction to cultivated areas should be carefully evaluated due to its effects on soil chemistry and microbiology. Short-term fallowing did not contribute to the maintenance of soil structure. Implications In a context of land uses change, modifications of microbial biomass and activity would affect megaaggregate formation and stability. Alternative management practices are required to maintain soil structure and optimize sustainable land use of cultivated and fallow fields.

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“…Tobiašová [46] similarly conducted a study on labile carbon content in different aggregate sizes and results revealed that macro-aggregates having size 0.25-1 mm had a maximum fraction of labile C especially labile C oxidizable with KMnO4. The aggregate fraction of size 0.5-1 mm was in a negative correlation with labile C fraction and appears to be a crucial indicator of changes in the ecosystems.…”

Section: Kmno4-cmentioning

confidence: 99%

Long-term Use of Balanced and Integrated Nutrient Management Improved Soil Aggregation and Carbon Stabilization in a Maize-wheat Cropping Sequence

Singh

Dheri

Benbi

2020

IJECC

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Sustainable nutrient management practices have the potential to enhance carbon (C) storage capacity of agricultural soils that may help offset increasing atmospheric CO2 concentration. Nutrient management practices on long-term basis differentially influence aggregates and distribution of soil organic C (SOC) present within aggregates, which in time may affect C stabilization. The present study assessed the impact of long-term application of fertilizers for 44 years either alone or integration with farmyard manure (FYM) on bulk density, SOC and C pools, potassium permanganate oxidizable C (KMnO4), aggregate stability and distribution of C fractions within different size aggregate under maize-wheat cropping sequence. The application of 100%NPK+FYM significantly (P< 0.05) improved soil aggregation and mean weight diameter (MWD). The percent of macro-aggregates (MacroA) and meso-aggregates (MesoA) was maximum in 100%NPK+FYM followed by NPK and the minimum in the control treatment. Irrespective of aggregate classes, TOC (g kg-1 aggregate) was maximum in 100%NPK+FYM treatment with an average of 8.42 g kg-1 aggregate as compared to control (5.05 g kg-1 aggregate). If averaged across the treatments, TOC concentration in aggregates followed the order MacroA> MesoA>MicroA. Correspondingly, results for KMnO4-C were similar in different treatments and aggregate classes. Application of FYM with inorganic fertilizers (NPK) or NPK showed a significant increase in all oxidizable organic C fractions particularly recalcitrant C fraction, which reflects the stable nature of OC as compared to very labile and labile C fractions. In general, C present in mineral fraction and large-sized aggregates (MacroA) has higher recalcitrant fractions of SOC as compared to small-sized aggregates (MesoF and MicroF). The study concluded that long-term balanced and integrated nutrient management improved soil aggregation, C distribution within aggregates, and C storage capacity of soils under maize-wheat. Carbon associated with macro aggregate and a mineral fraction has more recalcitrant C fraction compared to meso and micro aggregate fractions.

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Labile forms of carbon and soil aggregates

Cited by 10 publications

References 23 publications

Effects of Biochar on Soil Aggregation and Distribution of Organic Carbon Fractions in Aggregates

Effects of Biochar on Soil Aggregation and Distribution of Organic Carbon Fractions in Aggregates

Soil microbial biomass and oxy-hydroxides contribute to aggregate stability and size distribution under different land uses in the Central Andes

Long-term Use of Balanced and Integrated Nutrient Management Improved Soil Aggregation and Carbon Stabilization in a Maize-wheat Cropping Sequence

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