Abstract
In this work, lacunarity analysis is performed on soil pores segmented by the pure voxel extraction method from soil tomography images. The conversion of forest to sugarcane plantation was found to result in higher sugarcane soil pore lacunarity than that of native forest soil, while the porosity was found to be lower. More precisely, this study shows that native forest has more porous soil with a more uniform spatial distribution of pores, while sugarcane soil has lower porosity and a more heterogeneous pore distribution. Moreover, validation through multivariate statistics demonstrates that lacunarity can be considered a relevant index of clustering and can explain the variability among soils under different land use systems. While porosity by itself represents a fundamental concept for quantification of the impact of land use change, the current findings demonstrate that the spatial distribution of pores also plays an important role and that pore lacunarity can be adopted as a complementary tool in studies directed at quantifying the effect of human intervention on soils.
Highlights
Global social and economic changes during recent decades have led to an increasing demand for the conversion of natural areas for urbanization, agriculture, and livestock, as well as for wood extraction
The consistency of the pure voxel extraction (PVE) segmentation was verified by a higher porosity in native forest soils (Figure 2)
The analysis of lacunarity applied to soil tomography images of the pores segmented by the pure voxel extraction method was consistent in the evaluation of the impact of land use change, pointing to higher values in sugarcane soils
Summary
Global social and economic changes during recent decades have led to an increasing demand for the conversion of natural areas for urbanization, agriculture, and livestock, as well as for wood extraction. These processes have begun to threaten most tropical forests, increasing the rate of deforestation to up to 9.1 million hectares per year (Moraes, Mello, & Toppa, 2017). This degradation has immediate and negative effects on biodiversity, in part by causing fragmentation, i.e., the division of the natural environment into small, isolated blocks of land surrounded by human-modified landscapes. Despite the extent and significance of these ecosystems, there is little available scientific information about the effects of forest removal on their soil properties
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
