The Crop Succession Systems Under No-Tillage Alters the Surface Layer Soil Carbon Stock and Stability

The main challenge of the no-tillage system (NTS) is to reconcile productivity, the maintenance of surface residues, and the stabilization of soil organic matter (SOM). To address this challenge, particularly in tropical regions, various cover crops have been tested. The objective of this study was...

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Published in:Agriculture (Basel) 2024-11, Vol.14 (11), p.2085
Main Authors: de Souza, Paloma Pimentel, Machado, Deivid Lopes, de Freitas, Micael Silva, Bezerra, Aracy Camilla Tardin Pinheiro, Guimarães, Tiara Moraes, da Silva, Eder Marcos, do Nascimento, Natanael Moreira, Borges, Rafael da Silva, Costa, Vladimir Eliodoro, Costa, Claudio Hideo Martins da, Cruz, Simério Carlos Silva
Format: Article
Language:English
Subjects:
Agricultural practices
Autumn
Biomass
Carbon
Carbon 13
Carbon content
Carbon sequestration
Cereal crops
Composite materials
Corn
Cover crops
crop diversification
Crop residues
Crops
Decomposition
Density
Ecological succession
Experiments
Fractionation
Grain size
Harvest
Microorganisms
Millet
Nitrogen
No-till cropping
No-tillage
Organic carbon
Organic matter
Organic soils
pearl millet
Pennisetum glaucum
physical fractionation
Porosity
Productivity
soil carbon pool
Soil density
Soil layers
Soil organic matter
Soil porosity
Soil stability
Soil stabilization
Soil structure
Soil testing
Soils
Soybean
Soybeans
Stocks
Summer
Surface layers
Surface stability
Tillage
Total organic carbon
Tropical environment
Tropical environments
Urochloa ruziziensis
Vegetables
Winter
Zea mays
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Summary:The main challenge of the no-tillage system (NTS) is to reconcile productivity, the maintenance of surface residues, and the stabilization of soil organic matter (SOM). To address this challenge, particularly in tropical regions, various cover crops have been tested. The objective of this study was to test the effects of agricultural crop succession systems on the stock and stability of soil organic carbon in different surface layers of the soils. The research was carried out in the state of Goiás, Brazil, in an experiment set up in 2016, designed in randomized blocks with a split-plot scheme (treatments and soil layers), comprising four repetitions (blocks). The treatments (plots) consisted of crops grown in succession to soybean, which were as follows: T1—soybean/corn (Zea mays); T2—soybean/pearl millet (Pennisetum glaucum); T3—soybean/Urochloa ruziziensis (brachiaria); and T4—corn + Urochloa ruziziensis. The subplots represented the following soil layers: 0–5, 5–10, 10–20, and 20–40 cm. We evaluated the biomass dry mass and the soil parameters such as soil density, total porosity, and light organic matter across all layers. The organic carbon, grain size fractionation (mineral-associated organic carbon—MOC; sand-sized carbon—POC), and isotopic composition (δ13C) were determined in the 0–5 and 5–10 cm layers. The highest biomass dry production was observed in the soybean/pearl millet succession, which reduced the soil density and increased the total porosity in the surface layer. The soybean/pearl millet treatment produced high amounts of light organic matter, particularly in the 0–5 cm layer, a result also found for the soybean/brachiaria and soybean/corn + brachiaria systems. The crop successions did not alter the soil carbon stock or stability; however, the surface layer stored the highest amount of carbon, with elevated total organic carbon values and carbon stocks and stability (MOC and POC). Overall, in this study, replacing corn with other crops in succession with soybean did not affect the stock or stability of soil organic carbon. The species grown in succession with soybean contributed to the higher surface carbon stock and stability, promoting the formation of more stable and recalcitrant carbon.
ISSN:2077-0472
2077-0472
DOI:10.3390/agriculture14112085