Abstract
This study aims to assess the carbon stock in a pasture area and fragment of forest in natural regeneration, given the importance of agroforestry systems in mitigating gas emissions which contribute to the greenhouse effect, as well as promoting the maintenance of agricultural productivity. Our other goal was to predict the carbon stock, according to different land use systems, from physical and chemical soil variables using the Random Forest algorithm. We carried out our study at an Entisols Quartzipsamments area with a completely randomized experimental design: four treatments and six replites. The treatments consisted of the following: (i) an agroforestry system developed for livestock, (ii) an agroforestry system developed for fruit culture, (iii) a conventional pasture, and (iv) a forest fragment. Deformed and undeformed soil samples were collected in order to analyze their physical and chemical properties across two consecutive agricultural years. The response variable, carbon stock, was subjected to a boxplot analysis and all the databases were used for a predictive modeling which in turn used the Random Forest algorithm. Results led to the conclusion that the agroforestry systems developed both for fruit culture and livestock, are more efficient at stocking carbon in the soil than the pasture area and forest fragment undergoing natural regeneration. Nitrogen stock and land use systems are the most important variables to estimate carbon stock from the physical and chemical variables of soil using the Random Forest algorithm. The predictive models generated from the physical and chemical variables of soil, as well as the Random Forest algorithm, presented a high potential for predicting soil carbon stock and are sensitive to different land use systems.
Highlights
The use of agroforestry systems to achieve optimum agronomic benefits through the efficient use of resources has received great attention for its contribution to mitigating climate change through organic carbon sequestration [1]
The area cultivated in the pasture had the lowest carbon stock in relation to the remaining land use systems, followed by forest area (Figure 3)
The AFS2 was significant in relation to other land use systems for showing higher mean values for soil carbon stock in the superficial layers; values of 7.73 and 7.09 Mg ha−1 were observed at the layers of 0.00–0.05 and 0.05–0.10 m, respectively
Summary
The use of agroforestry systems to achieve optimum agronomic benefits through the efficient use of resources (nutrients, light, water collection, and utilization) has received great attention for its contribution to mitigating climate change through organic carbon sequestration [1]. In this context, understanding the dynamics and storage of soil carbon, especially in agroforestry systems, is essential for informing public policies focused on disseminating these agricultural practices [2]. If carbon inlets are higher than outlets (through mineralization or erosion) soil carbon stock increases [7]
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