Aggregate mass and carbon stocks in a paddy soil after long‐term application of chemical or organic fertilizers

Qiu, Shaojun; Nie, J.; ShiPing, Long; Lu, Yanhong; Zhao, Shicheng; Xu, Xinpeng; Ping, He; Liao, Yulin; Zhou, Wei

doi:10.1111/sum.12807

Cited by 6 publications

(2 citation statements)

References 53 publications

(113 reference statements)

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“…Therefore, understanding the EOC content and carbon pool management index (CPMI) variable characteristics in various particle size aggregates would help better understand SOC’s stability mechanism. However, prior studies on the sequestration of organic carbon in soil aggregates mostly concentrated on the content of TOC ( Liu et al., 2019 ; Qiu et al., 2022 ), and there was comparatively little research on the active organic carbon in aggregates.…”

Section: Introductionmentioning

confidence: 99%

Influence of long-term fertilization on soil aggregates stability and organic carbon occurrence characteristics in karst yellow soil of Southwest China

et al. 2023

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Current research has long focused on soil organic carbon and soil aggregates stability. However, the effects of different long-term fertilization on the composition of yellow soil aggregates and the characteristics of the occurrence of organic carbon in the karst region of Southwest China are still unclear. Based on a 25-year long-term located experiment on yellow soil, soil samples from the 0–20 cm soil layer were collected and treated with different fertilizers (CK: unfertilized control; NPK: chemical fertilizer; 1/4 M + 3/4 NP: 25% chemical fertilizer replaced by 25% organic fertilizer; 1/2 M + 1/2 NP: 50% chemical fertilizer replaced by organic fertilizer; and M: organic fertilizer). In water-stable aggregates, soil aggregates stability, total organic carbon (TOC), easily oxidized organic carbon (EOC), carbon preservation capacity (CPC), and carbon pool management index (CPMI) were analyzed. The findings demonstrated that the order of the average weight diameter (MWD), geometric mean diameter (GWD), and macro-aggregate content (R0.25) of stable water aggregates was M > CK > 1/2M +1/2NP > 1/4M +3/4NP> NPK. The MWD, GWD, and R0.25 of NPK treatment significantly decreased by 32.6%, 43.2%, and 7.0 percentage points, respectively, compared to CK treatment. The order of TOC and EOC content in aggregates of different particle sizes was M > 1/2M +1/2NP > 1/4M +3/4NP> CK > NPK, and it increased as the rate of organic fertilizer increased. In macro-aggregates and bulk soil, the CPC of TOC (TOPC) and EOC (EOPC), as well as CPMI, were arranged as M > 1/2M +1/2NP > 1/4M +3/4NP> CK > NPK, but the opposite was true for micro-aggregates. In bulk soil treated with organic fertilizer, the TOPC, EOPC, and CPMI significantly increased by 27.4%–53.8%, 29.7%–78.1%, 29.7–82.2 percentage points, respectively, compared to NPK treatment. Redundancy analysis and stepwise regression analysis show that TOC was the main physical and chemical factor affecting the aggregates stability, and the TOPC in micro-aggregates has the most direct impact. In conclusion, the primary cause of the decrease in SOC caused by the long-term application of chemical fertilizer was the loss of organic carbon in macro-aggregates. An essential method to increase soil nutrient supply and improve yellow soil productivity was to apply an organic fertilizer to increase aggregates stability, storage and activity of SOC in macro-aggregates.

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Section: Introductionmentioning

confidence: 99%

Influence of long-term fertilization on soil aggregates stability and organic carbon occurrence characteristics in karst yellow soil of Southwest China

et al. 2023

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“…Recent attempts have been made to reduce organic carbon loss from soils for climate change mitigation, whose measures include crop residue incorporation (Lupwayi et al 2022;Zhu et al 2022a), organic matter stabilization with clay and metal oxides (Baumann et al 2022;Di et al 2022), fertilizer application (da Silva et al 2022;Gasser et al 2022;Qiu et al 2022;Thakur et al 2022;Zhang et al 2022b), reduced or conservational tillage (Ferrara et al 2022;He et al 2022a;Islam et al 2022), rotational grazing (Abdalla et al 2022;Dong et al 2021), silvopastoral system (Aryal et al 2019;Valenzuela Que et al 2022), and ecological restoration (Howson et al 2022;Wang et al 2020b;Zhao et al 2022). Among them, application of biochar is a promising one due to simultaneous achievement of waste management, nutrient delivery, contaminant immobilization, and climate change mitigation.…”

Section: Co 2 Emissionsmentioning

confidence: 99%

Role of biochar toward carbon neutrality

et al. 2023

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Carbon neutrality by the mid-twenty-first century is a grand challenge requiring technological innovations. Biochar, a traditional soil amendment which has been used for fertility improvement and contaminant remediation, has revealed new vitality in this context. In this review we highlight the huge potential of biochar application in different fields to mitigate as high as 2.56 × 109 t CO2e total greenhouse gas (GHG) emissions per year, accounting for 5.0% of the global GHG emissions. Soil applications of biochar as either a controlled-release fertilizer or an immobilization agent offer improved soil health while simultaneously suppressing the emissions of CH4 and N2O. Non-soil applications of biochar also contribute to carbon neutrality in unique ways. Firstly, biochar application as a ruminant feed decreases CH4 emissions via physical sorption and enhanced activities of methanotrophs. Secondly, biochar can be used as a green catalyst for biorefinery. Besides, biochar as an additive to Portland cement and low impact development (LID) infrastructure lowers the carbon footprint and builds resilience to climate change. Furthermore, biochar can be used as novel batteries and supercapacitors for energy storage purposes. Finally, the high CO2 adsorption capacity makes it possible for biochar being used as a sorbent for carbon capture, utilization, and storage (CCUS). We advocate that future research should further explore the effectiveness of biochar systems for climate change mitigation in large scale applications, and assess the economic and social viability of local biochar systems to combat climate change. Graphical Abstract

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Response of soil aggregation and associated organic carbon to organic amendment and its controls: A global meta-analysis

Ma,

Cao,

et al. 2024

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Aggregate mass and carbon stocks in a paddy soil after long‐term application of chemical or organic fertilizers

Cited by 6 publications

References 53 publications

Influence of long-term fertilization on soil aggregates stability and organic carbon occurrence characteristics in karst yellow soil of Southwest China

Influence of long-term fertilization on soil aggregates stability and organic carbon occurrence characteristics in karst yellow soil of Southwest China

Role of biochar toward carbon neutrality

Response of soil aggregation and associated organic carbon to organic amendment and its controls: A global meta-analysis

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