Vertical dynamics of dissolved organic carbon in relation to organic input quality and microaggregate formation in a coarse– textured Ultisol

Kunlanit, Benjapon; Rasche, Frank; Puttaso, Aunnop; Cadisch, Georg; Vityakon, Patma

doi:10.1111/ejss.12874

Cited by 6 publications

(3 citation statements)

References 32 publications

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“…Yet, Angst et al (2021) recently suggested that sorption of DOC to particles could be of equal importance. For example, low molecular weight DOC contributed to increased levels of bulk soil C at lower depths through leaching in the same long-term experiment as used in this study (Kunlanit et al 2020). However, our findings cannot distinguish if transferred DOC is primarily attached to SiCl in the form of microbially synthesized products by the microbes feeding on the DOC, or whether microbially depolymerized DOC attaches directly to SiCl surfaces without further microbial interaction.…”

Section: Discussionmentioning

confidence: 69%

Litter Quality and Microbes Explain Aggregation Differences in a Tropical Sandy Soil

Laub

Schlichenmeier

Vityakon

et al. 2021

J Soil Sci Plant Nutr

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Soil aggregates store most soil organic carbon (SOC), but how does litter quality influence their formation? We hypothesized varying litter quality to facilitate differences in aggregate formation by altering the seasonal development of microbial biomass (MB) C and N, with MB driving aggregate development in a tropical sandy soil in Thailand. Aggregate development was studied in a long-term fallow experiment, receiving 10 Mg ha−1 annual applications of rice (Oryza sativa) straw (low N and polyphenols (PP)), groundnut (Arachis hypogaea) stover (high N, low PP), tamarind (Tamarindus indica) litter (medium N and PP), or dipterocarp (Dipterocarpus tuberculatus) leaf litter (low N, high PP) compared to a control. N-rich litter from groundnut and tamarind led to significantly higher MB, bulk soil C and aggregate C than dipterocarp, rice straw, and the control. Bulk soil C and small macroaggregates C of N-rich litter treatments increased about 7% in 30 weeks. Increasing MB N explained increasing small macroaggregate C and both, MB C or N were important covariates explaining temporal variations of C stored in the microaggregates, in silt and clay. MB also explained temporal variations of aggregate fraction weights. With time, SMA C only increased in the N-rich groundnut and tamarind treatments, but decreased in other treatments. Connections of MB to aggregate C and weight substantiated the importance of microbial activity for aggregate formation and carbon sequestration. By promoting MB for longest time spans, medium-quality tamarind could best facilitate aggregate formation, and increase silt and clay C.

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Section: Discussionmentioning

confidence: 69%

Litter Quality and Microbes Explain Aggregation Differences in a Tropical Sandy Soil

Laub

Schlichenmeier

Vityakon

et al. 2021

J Soil Sci Plant Nutr

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“…In contrast, C = C aromatic pools were shown to increase soil C stabilization (Haynes, 2005). It is acknowledged that the labile SOC pool can benefit important soil functions, including soil aggregate formation and nutrient supply as well as serve as essential microbial energy source (Ghani et al., 2003; Haynes, 2005; Kunlanit et al., 2020; Maia et al., 2007).…”

Section: Discussionmentioning

confidence: 99%

Agro‐ecology, resource endowment and indigenous knowledge interactions modulate soil fertility in mixed farming systems in Central and Western Ethiopia

Agumas

Balume

Musyoki

et al. 2021

Soil Use and Management

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“…Unfortunately, the use of rice straw as a soil amendment does not promote SOC accumulation because it has high CL but low N and L, resulting in rapid decomposition that leads to C loss as CO 2 [3,9]. In addition, the dissolved organic carbon (DOC) produced by decomposing RS is easily leached from topsoil because of its low molecular weight, which further limits SOC accumulation [10]. Moreover, because RS has low N content, it does not improve soil N status.…”

Section: Introductionmentioning

confidence: 99%

Nonadditive Effects on Decomposition of a Mixture of Rice Straw and Groundnut Stover Applied to a Sandy Soil

Pingthaisong

Vityakon

2021

Agronomy

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Rice straw is an abundant resource, but its use as a sandy soil amendment does not increase soil organic matter (SOM) accumulation. Our study aimed to determine the altered decomposition processes that result from mixing rice straw (RS) (low N, high cellulose) with groundnut stover (GN) (high N) relative to applying these residues singly to a sandy soil to identify the mechanisms underlying decomposition of the mixed residues. A microcosm experiment using the litter bag technique showed synergistic, nonadditive effects (observed < predicted values) of residue mass remaining (31.1% < 40.3% initial) that were concomitant with chemical constituent loss, including C (cellulose, lignin) and N. The nonadditive effects of soil microbiological parameters in response to the applied residues were synergistic (observed > predicted values) for microbial biomass C (MBC) (92.1 > 58.4 mg C kg−1 soil) and antagonistic (observed < predicted values) for microbial metabolic quotient (i.e., the inverse of microbial C use efficiency (CUE)) (0.03 < 0.06 mmol CO2-C • mmol MBC−1 • hr−1) and N mineralization (14.8 < 16.0 mg N kg−1 soil). In the early stage of decomposition (0–14 days), mixed residues increased MBC relative to the single residues, while they decreased N mineralization relative to single GN (p ≤ 0.05). These results indicate an increase in microbial substrate CUE and N use efficiency (NUE) in the mixed residues relative to the single residues. This increased efficiency provides a basis for the synthesis of microbial products that contribute to the formation of the stable SOM pool. The SOM stabilization could bring about the SOM accumulation that is lacking under the single-RS application.

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Vertical dynamics of dissolved organic carbon in relation to organic input quality and microaggregate formation in a coarse– textured Ultisol

Cited by 6 publications

References 32 publications

Litter Quality and Microbes Explain Aggregation Differences in a Tropical Sandy Soil

Litter Quality and Microbes Explain Aggregation Differences in a Tropical Sandy Soil

Agro‐ecology, resource endowment and indigenous knowledge interactions modulate soil fertility in mixed farming systems in Central and Western Ethiopia

Nonadditive Effects on Decomposition of a Mixture of Rice Straw and Groundnut Stover Applied to a Sandy Soil

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