Soil loss estimated by means of the RUSLE model in a subtropical climate watershed

Soil loss estimated by means of the RUSLE model in a subtropical climate watershed

ABSTRACT Erosion process occurs naturally, shaping the Earth’s surface. Soil loss can cause harmful effects to the environment when intensive anthropic activities occur. Mathematical models have been used as effective and less costly alternatives for identifying sites highly prone to soil loss, especially at the watershed scale. In Brazil, the Revised Universal Soil Loss Equation (RUSLE) is one of the most commonly used soil loss prediction models. The RUSLE requires information on soil erodibility, rainfall erosivity, topography, land use and cover (C), and conservation practices (P) to estimate average annual soil losses. Images derived from remote sensing techniques are generally used to quantify the spatialization of C factor; however, the variation in land use throughout the year is not usually considered. This study aimed to estimate soil losses in an important subwatershed of Candiota river watershed (CRWsub) by using RUSLE, considering land use and rainfall erosivity in different periods of the year. The periods considered were P1 (January, February and March), P2 (April, May and June), P3 (July, August and September) and P4 (October, November and December). Based on the results, the lowest soil losses occurred in P1. Probably, the high vegetation cover in the soil increases its protection against rainfall erosivity. In P3, the heavy rainfall events are predominantly frontal, occurring in the same months as those when the preparation of the soil for later planting takes place; that is, there is no vegetation cover in this period, thus making the soil more prone to erosion. The use of different images to classify and identify land uses is the best way to understand soil losses throughout the year in the study area. It was possible to observe that agricultural areas are generally associated with greater soil losses in the subwatershed. In addition, the land uses were considered to vary quarterly, thereby making it possible to identify the periods most prone to erosion processes throughout the year. Finally, the erosion percentages in the subwatershed can be linked to the tolerance index for different land-uses, soil classes, and slope categories.

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Main Authors: Zanchin,Mayara, Moura,Maíra Martim de, Nunes,Maria Cândida Moitinho, Beskow,Samuel, Miguel,Pablo, Lima,Cláudia Liane Rodrigues de, Bressiani,Danielle de Almeida
Format: Digital revista
Language:English
Published: Sociedade Brasileira de Ciência do Solo 2021
Online Access:http://old.scielo.br/scielo.php?script=sci_arttext&pid=S0100-06832021000100521
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spelling oai:scielo:S0100-068320210001005212021-12-03Soil loss estimated by means of the RUSLE model in a subtropical climate watershedZanchin,MayaraMoura,Maíra Martim deNunes,Maria Cândida MoitinhoBeskow,SamuelMiguel,PabloLima,Cláudia Liane Rodrigues deBressiani,Danielle de Almeida spatio-temporal analysis erosion tolerance index Candiota river ABSTRACT Erosion process occurs naturally, shaping the Earth’s surface. Soil loss can cause harmful effects to the environment when intensive anthropic activities occur. Mathematical models have been used as effective and less costly alternatives for identifying sites highly prone to soil loss, especially at the watershed scale. In Brazil, the Revised Universal Soil Loss Equation (RUSLE) is one of the most commonly used soil loss prediction models. The RUSLE requires information on soil erodibility, rainfall erosivity, topography, land use and cover (C), and conservation practices (P) to estimate average annual soil losses. Images derived from remote sensing techniques are generally used to quantify the spatialization of C factor; however, the variation in land use throughout the year is not usually considered. This study aimed to estimate soil losses in an important subwatershed of Candiota river watershed (CRWsub) by using RUSLE, considering land use and rainfall erosivity in different periods of the year. The periods considered were P1 (January, February and March), P2 (April, May and June), P3 (July, August and September) and P4 (October, November and December). Based on the results, the lowest soil losses occurred in P1. Probably, the high vegetation cover in the soil increases its protection against rainfall erosivity. In P3, the heavy rainfall events are predominantly frontal, occurring in the same months as those when the preparation of the soil for later planting takes place; that is, there is no vegetation cover in this period, thus making the soil more prone to erosion. The use of different images to classify and identify land uses is the best way to understand soil losses throughout the year in the study area. It was possible to observe that agricultural areas are generally associated with greater soil losses in the subwatershed. In addition, the land uses were considered to vary quarterly, thereby making it possible to identify the periods most prone to erosion processes throughout the year. Finally, the erosion percentages in the subwatershed can be linked to the tolerance index for different land-uses, soil classes, and slope categories.info:eu-repo/semantics/openAccessSociedade Brasileira de Ciência do SoloRevista Brasileira de Ciência do Solo v.45 20212021-01-01info:eu-repo/semantics/articletext/htmlhttp://old.scielo.br/scielo.php?script=sci_arttext&pid=S0100-06832021000100521en10.36783/18069657rbcs20210050
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country Brasil
countrycode BR
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access En linea
databasecode rev-scielo-br
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region America del Sur
libraryname SciELO
language English
format Digital
author Zanchin,Mayara
Moura,Maíra Martim de
Nunes,Maria Cândida Moitinho
Beskow,Samuel
Miguel,Pablo
Lima,Cláudia Liane Rodrigues de
Bressiani,Danielle de Almeida
spellingShingle Zanchin,Mayara
Moura,Maíra Martim de
Nunes,Maria Cândida Moitinho
Beskow,Samuel
Miguel,Pablo
Lima,Cláudia Liane Rodrigues de
Bressiani,Danielle de Almeida
Soil loss estimated by means of the RUSLE model in a subtropical climate watershed
author_facet Zanchin,Mayara
Moura,Maíra Martim de
Nunes,Maria Cândida Moitinho
Beskow,Samuel
Miguel,Pablo
Lima,Cláudia Liane Rodrigues de
Bressiani,Danielle de Almeida
author_sort Zanchin,Mayara
title Soil loss estimated by means of the RUSLE model in a subtropical climate watershed
title_short Soil loss estimated by means of the RUSLE model in a subtropical climate watershed
title_full Soil loss estimated by means of the RUSLE model in a subtropical climate watershed
title_fullStr Soil loss estimated by means of the RUSLE model in a subtropical climate watershed
title_full_unstemmed Soil loss estimated by means of the RUSLE model in a subtropical climate watershed
title_sort soil loss estimated by means of the rusle model in a subtropical climate watershed
description ABSTRACT Erosion process occurs naturally, shaping the Earth’s surface. Soil loss can cause harmful effects to the environment when intensive anthropic activities occur. Mathematical models have been used as effective and less costly alternatives for identifying sites highly prone to soil loss, especially at the watershed scale. In Brazil, the Revised Universal Soil Loss Equation (RUSLE) is one of the most commonly used soil loss prediction models. The RUSLE requires information on soil erodibility, rainfall erosivity, topography, land use and cover (C), and conservation practices (P) to estimate average annual soil losses. Images derived from remote sensing techniques are generally used to quantify the spatialization of C factor; however, the variation in land use throughout the year is not usually considered. This study aimed to estimate soil losses in an important subwatershed of Candiota river watershed (CRWsub) by using RUSLE, considering land use and rainfall erosivity in different periods of the year. The periods considered were P1 (January, February and March), P2 (April, May and June), P3 (July, August and September) and P4 (October, November and December). Based on the results, the lowest soil losses occurred in P1. Probably, the high vegetation cover in the soil increases its protection against rainfall erosivity. In P3, the heavy rainfall events are predominantly frontal, occurring in the same months as those when the preparation of the soil for later planting takes place; that is, there is no vegetation cover in this period, thus making the soil more prone to erosion. The use of different images to classify and identify land uses is the best way to understand soil losses throughout the year in the study area. It was possible to observe that agricultural areas are generally associated with greater soil losses in the subwatershed. In addition, the land uses were considered to vary quarterly, thereby making it possible to identify the periods most prone to erosion processes throughout the year. Finally, the erosion percentages in the subwatershed can be linked to the tolerance index for different land-uses, soil classes, and slope categories.
publisher Sociedade Brasileira de Ciência do Solo
publishDate 2021
url http://old.scielo.br/scielo.php?script=sci_arttext&pid=S0100-06832021000100521
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