Conservation agriculture can provide a low-cost competitive option to mitigate global warming with reduction or elimination of soil tillage and increase soil organic carbon (SOC). Most studies have evaluated the impact of zero till (ZT) only on surface soil layers (down to 30 cm), and few studies have been performed on the potential for C accumulation in deeper layers (0-100 cm) of tropical and subtropical soils. In order to determine whether the change from conventional tillage (CT) to ZT has induced a net gain in SOC, three long-term experiments (15-26 years) on free-draining Ferralsols in the subtropical region of South Brazil were sampled and the SOC stocks to 30 and 100 cm calculated on an equivalent soil mass basis. In rotations containing intercropped or cover-crop legumes, there were significant accumulations of SOC in ZT soils varying from 5 to 8 Mg ha À1 in comparison with CT management, equivalent to annual soil C accumulation rates of between 0.04 and 0.88 Mg ha À1 . However, the potential for soil C accumulation was considerably increased (varying from 0.48 to 1.53 Mg ha À1 yr À1 ) when considering the soil profile down to 100 cm depth. On average the estimate of soil C accumulation to 100 cm depth was 59% greater than that for soil C accumulated to 30 cm. These findings suggest that increasing sampling depth from 30 cm (as presently recommended by the IPCC) to 100 cm, may increase substantially the estimates of potential CO 2 mitigation induced by the change from CT to ZT on the free-draining Ferralsols of the tropics and subtropics. It was evident that that legumes which contributed a net input of biologically fixed N played an important role in promoting soil C accumulation in these soils under ZT, perhaps due to a slow-release of N from decaying surface residues/roots which favored maize root growth.
Recent studies have shown harmful effects of soil compaction in no-tillage system (NTS), but there are indications that soil structure improves with time of NTS adoption. We formulated the hypothesis that topsoils of NTS initially have worse soil physical conditions than those under conventional systems, but these conditions gradually improve with time also down to deeper depth, even when the soil is wheeled by farm machinery. Our objective was to evaluate the effect of a long-term no-tillage system and machine traffic on soil mechanical and hydraulic properties. The treatments and soil conditions consisted of five periods since the last conventional tillage (or age of NTS) in a Hapludox: 0.2, 1.5, 3.5, 5 and 14 years, with and without traffic; named recent tillage, and initial, intermediate, transition and stabilized NTS phases. Soil samples were collected from soil layers 0-7, 7-14 and 14-21 cm depth to determine soil porosity, precompression stress, compressibility coefficient, saturated hydraulic conductivity, air permeability, water retention curve, bulk density and organic carbon. Conventional tillage of soil previously under notillage significantly affected soil capacity properties, resulting in high macroporosity and deformation susceptibility, low bulk density and precompression stress. Intensity properties were affected initially by an increased soil pore obstruction, negatively affecting air permeability and saturated hydraulic conductivity, from 0 to 21 cm soil depth. However, after five years of no-tillage there was an increase in microporosity and, although small, in soil organic carbon, especially in the 0-7 cm soil layer; thus, soil water retention and soil intensity properties (like soil water and air permeability) were also improved, regardless of farm machinery traffic. Over time, soil reconsolidation occurred, which resulted in reduction of the compressibility coefficient and degree of compactness, mainly in the upper layers (0-7 and 7-14 cm). However, in the deepest layer with the least disturbance, the degree-of-compactness and bulk density increased. The evolution of physical properties and processes (from recent tillage to stabilized NTS phase) for no-tilled soil is proposed for controlled and uncontrolled traffic systems as a framework based on field data for capacity and intensity soil properties. The process of creating aggregates is represented, at first, by an increased number of contact points before they are re-loosened and strengthened at the same time by a rearrangement of particles, reducing aggregate bulk density but increasing soil strength at the same time. The framework is divided into 4 phases: initial (1.5 years), intermediary (3.5 years), transitional (5 years), and stabilized (14 years) conditions. 2015 Elsevier B.V. All rights reserved.
Soil physical properties Development of corn plants Fixed shank openers A B S T R A C TSoil compaction has always been a problem to the agricultural productivity, mainly in clayey soils under the no-tillage (NT). Alternatives to mitigate this problem are necessary. The aim of this study was to evaluate the effect of seeder equipped with fixed shanks openers, working at three depths, in a Ferralic Nitisol (Rhodic), under NT on the mitigation of soil compaction and corn (Zea mays L.) plant development. The test comprised three treatments regarding the depth at which the shank openers of a seeder used to sow corn worked: openers reaching up to 0.05 m; openers reaching up to 0.07 m; and openers reaching up to 0.17 m. The effect of these treatments was evaluated in relation to the determination of soil physical parameters, and corn plant parameters. The use of a seeder equipped with fixed shanks openers up to 0.17 m depth caused an increase in soil macroporosity and total porosity, and a decrease in soil bulk density, soil resistance to penetration and degree of compactness in the layer between 0.07 and 0.17 m. The improved physical conditions of the soil in this layer led to a further development of the root system of plants in greater depth, and consequently to a better development of corn plants with higher stalk diameter, root density and root length. The use of a seeder equipped with fixed shanks openers working up to 0.17 m depth, therefore, promoted physical improvement to the soil, favoring the development of corn plants, and presenting potential to mitigate the compaction of clayey soils under NT.
Resumo -O objetivo deste trabalho foi determinar o tempo de duração do efeito da descompactação do solo, por escarificação mecânica, por meio de indicadores físico-hídricos de Latossolo argiloso, manejado em sistema plantio direto (SPD). Os tratamentos consistiram em meses (0, 6, 12, 18, 24, 30 e 36) transcorridos após escarificação mecânica em SPD e em testemunha sem escarificação em SPD há 27 anos. Foram avaliadas as variáveis: resistência mecânica à penetração, taxa de infiltração de água no solo, densidade e densidade relativa do solo, distribuição do tamanho de poros e condutividade hidráulica do solo saturado. A duração dos efeitos da escarificação mecânica variou com a propriedade do solo, tendo se mantido por 6 meses na densidade e na densidade relativa, na porosidade total e na macroporosidade; 18 meses na resistência à penetração; e 24 meses na condutividade hidráulica e na taxa de infiltração de água no solo. Propriedades do solo relacionadas ao transporte de água, como condutividade hidráulica e taxa de infiltração estável de água no solo, mantêm o efeito da escarificação por mais tempo e, portanto, são mais adequadas para avaliar a duração da descompactação mecânica.Termos para indexação: compactação, descompactação mecânica, estrutura do solo, manejo do solo. Duration of changes in physical and hydraulic properties of a clayey Oxisol by mechanical chiselingAbstract -The objective of this work was to determine the duration of the effects of soil decompaction, by mechanical chiseling, through physical and hydraulic indicators of a clayey Oxisol under no-tillage (NT). The treatments consisted of months (0, 6, 12, 18, 24, 30, and 36) after chiseling under NT and of a control treatment without chiseling under NT during 27 years. The following variables were evaluated: penetration resistance, infiltration rate, bulk density and relative density, pore size distribution, and saturated hydraulic conductivity. The duration of the effects of mechanical chiseling varied according to the evaluated soil property, lasting six months for bulk density and relative density, total porosity, and macroporosity; 18 months for penetration resistance; and 24 months for hydraulic conductivity and infiltration rate. Soil properties related to water transport, such as hydraulic conductivity and steady infiltration rate, maintain the effect of mechanical chiseling for a longer time and, therefore, are more suitable to measure the duration of mechanical decompaction.
RESUMOA compactação tornou-se uma das principais causas de degradação do solo em áreas agrícolas, estando diretamente relacionada ao sistema de manejo do solo adotado e, muitas vezes, demandando práticas de descompactação para mitigar esse problema. Este trabalho objetivou avaliar a duração do efeito de intervenções mecânicas, como a aração e escarificação do solo associadas à ação de semeadora de plantio direto equipada com mecanismos rompedores de solo tipo discos e discos + facão, como práticas mitigadoras da compactação de um solo manejado sob o Sistema Plantio Direto (SPD), por meio da avaliação de atributos físicos do solo e do esforço de tração. O estudo foi realizado no município de Coxilha, na região Norte do Rio Grande do Sul, localizado nas coordenadas geográficas de 28°10'18,7" S e 52°22'39,89" O, sobre um Latossolo Vermelho, em experimento instalado no ano de 2001 em área com histórico de oito anos sob SPD. Nessa área foram realizadas intervenções mecânicas anuais, mediante a aração e escarificação do solo, anteriores à implantação da cultura de verão. Os tratamentos de manejo do solo constituíram-se da testemunha, com manutenção ininterrupta do SPD por 16 anos e por seis períodos de tempo de condução desse sistema (7,5; 6,5; 5,5; 4,5; 3,5; e 2,5 anos) após a escarificação ou aração, aplicados nas parcelas principais. Nas subparcelas foram aplicados dois tratamentos de dispositivo de aplicação do adubo no sulco de semeadura (discos duplos defasados e facão + discos
RESUMOA infiltração de água é uma propriedade que reflete as condições físicas do solo, principalmente quanto à sua qualidade estrutural. Foi realizado um estudo na Embrapa Trigo, em Passo Fundo (RS), em um Latossolo Vermelho-Escuro, submetido por longo tempo a diferentes sistemas de manejo, com o objetivo de verificar a influência desses sistemas na taxa de infiltração de água, considerando as diferentes coberturas de solo e condições físicas gerais por eles propiciadas. A área experimental estava cultivada com milho, tendo-se aplicado chuva simulada de 120 mm h -1 , durante 90 minutos, em três repetições, em três épocas distintas: (a) 45 dias após a semeadura do milho; (b) logo após a colheita do milho e (c) logo após a semeadura de aveia. As chuvas simuladas foram aplicadas sobre parcelas de 0,81 m 2 distribuídas dentro de macroparcelas com os sistemas de manejo em preparo convencional, cultivo mínimo e sistema plantio direto. O cultivo mínimo apresentou, em todas as épocas, as maiores taxas de infiltração de água no solo, e o sistema plantio direto produziu as maiores quantidades de palha na superfície do solo.Termos de indexação: taxa de infiltração, chuva simulada, plantio direto, cobertura do solo, resíduos de milho.
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