João Paulo Cassol Flores

Managing grazing animals to achieve nutrient cycling and soil improvement in no-till integrated systems

Crop-livestock systems are regaining their importance as an alternative to unsustainable intensive farming systems. Loss of biodiversity, nutrient pollution and habitat fragmentation are a few of many concerns recently reported with modern agriculture. Integrating crops and pastures in no-till systems can result in better environmental services, since conservation agriculture is improved by system diversity, paths of nutrient flux, and other processes common in nature. The presence of large herbivores can positively modify nutrient pathways and soil aggregation, increasing soil quality. Despite the low diversity involved, the integration of crops and pastures enhances nature’s biomimicry and allows attainment of a higher system organization level. This paper illustrates these benefits focusing on the use of grazing animals integrated with crops under no-tillage systems characteristic of southern Brazil.

Evolução de atributos físicos de solo em sistema de integração lavoura-pecuária

The objective of this work was to assess the effect of sward height and successive grazing cycles over soil physical attributes in an integrated crop-livestock system. The experiment was established in 2001, in the Planalto Medio region, RS, Brazil, in a Rhodic Hapludox (Oxisol), with annual ryegrass (Lolium multiflorum) intercropped with black oat (Avena strigosa), under continuous grazing, during the winter, and single cropped soybean (Glycine max) during the summer. The treatments consisted of different grazing intensities, determined by sward height (10, 20, 30, and 40 cm), and a no-grazing area was used as a control. Soil bulk density and soil porosity were evaluated at the end of the grazing and soybean cycles, as well as soil resistance to mechanic penetration and aggregate stability in the seventh year of the experiment. No significant differences were found on soil bulk density and soil porosity after seven years under crop-livestock integration. Soil resistance to penetration is higher on the superficial layer after the grazing cycle. Soil aggregation increases in grazing areas, regardless of grazing intensities.

Distribuição de potássio e de raízes no solo e crescimento de milho em sistemas de manejo do solo e da adubação em longo prazo

Soil tillage systems can greatly influence potassium and root distribution in the soil and, as a result, affect corn growth and development. To improve the understanding of these interrelationships, a soil was analyzed after 18 years of cultivation under different management systems. A detailed soil sampling was carried out in a clayey Red Argisol (Udult) profile in the beginning of the grain filling stage of corn in the 2006/07 growing season. The experimental design consisted of a completely randomized scheme with two replicates, with the following treatments: conventional tillage (Con) and no-tillage (Dir) with potassium fertilization: along the rows (Fx), broadcast (Lan) and in stripes (Lin). Independently of the soil and fertilizer management, potassium formed gradients from the soil surface downwards and around the corn plant stem. The gradients, however, differed according to the soil management; concentrations were higher at the surface under no-tillage, regardless of the fertilization method. Maize roots were concentrated predominantly in the soil surface layer, with greater growth in no-tillage. Potassium uptake and maize growth were not associated with K distribution in soil and roots. The efficiency of K use by plants was increased by the broadcast application of potassium fertilizer, regardless of the tillage system.