Spatial variability of precompression stress and volumetric water content of a red-yellow latosol (Oxisol)

Spatial variability of precompression stress and volumetric water content of a red-yellow latosol (Oxisol)

The intensive agricultural machinery traffic to which soils under coffee crops are exposed may cause significant changes in soil structure. The goals of this study were to: a) characterize the spatial variability of precompression stress (σp) and volumetric water content (θ) of a Red-Yellow Latosol...

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Bibliographic Details
Published in:Bioscience journal Vol. 36; no. 1; pp. 142 - 151
Main Authors: Kamimura, Karina Marie, Dias Júnior, Moacir de Souza, Oliveira, Marcelo Silva de, Santos, Gérson Rodrigues dos, Guimarães, Paulo Tácito Gontijo, Ajayi, Ayodele Ebenezer
Format: Journal Article
Language:English
Published: Universidade Federal de Uberlândia 01-01-2020
Subjects:
compactation
geostatistics
load bearing capacity
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Summary:The intensive agricultural machinery traffic to which soils under coffee crops are exposed may cause significant changes in soil structure. The goals of this study were to: a) characterize the spatial variability of precompression stress (σp) and volumetric water content (θ) of a Red-Yellow Latosol (Oxisol) and determine their spatially dependent structures using ordinary kriging semivariograms; b) using this date to construct a load-bearing capacity (LBC) map for the site, identifying the depth with higher ; and c) use the map as a decision support tool regarding agricultural machinery logistic management in coffee plantations. The research was conducted on an experimental farm of the Agricultural Research Company of Minas Gerais (Epamig), Patrocinio, MG, on a clayey Oxisol. Samples were collected from 2.0 × 1.5 m sampling pits at intersections of a rectangular 40 × 150 m grid, totaling 28 sampling points. The soil samples were collected with metal rings (0.0254 m in height and 0.0630 m in diameter) using an Uhland sampler. Sampling at each pit was at 3 layers: 0.00–0.03 m, 0.10–0.13 m, and 0.25–0.28 m, and seven samples arranged in a matrix form were collected at each layer, totaling 588 samples. The σp and θ showed a spatially dependent structure. The depth of 0.00–0.03 m showed higher LBC, indicating that this depth was more compacted compared to other depths. Based on the σp maps, the tractor and the combine should not traffic into the areas at water content of 0.45 m3 m-3, because the soil has a LBC of 200 kPa. If this condition is not respected, additional compaction will occur. Tractor traffic is permissible when the water content reaches values less than 0.36 m3 m-3, whereas for combine traffic, the water content values must be less than 0.30 m3 m-3.
ISSN:1981-3163
1981-3163
DOI:10.14393/BJ-v36n1a2020-42121