Brachiaria As A Cover Crop To Improve Phosphorus Use Efficiency In A No-till Oxisol

Oxidic soils are phosphorus drains in soil; hence, P availability is a limiting factor in tropical, weathered Oxidic soils. It has been shown that some brachiarias grown as cover crops may increase soil available P to subsequent crops. The objective of this study was to evaluate soil P cycling and availability, as well as the response of soybean to soluble and natural reactive phosphates as affected by ruzi grass (Urochloa ruziziensis, R. Germ. and C.M. Evrard, Crin) grown as a cover crop in a no-till system. Experimental treatments consisted of the presence or absence of ruzi grass in combination with a control (0.0 P) and soluble and reactive rock phosphate broadcast on the soil surface in the winter (80 kg ha-1 P2O2), plus three rates of P applied to soybean furrows (0, 30, and 60 kg ha-1 of P2O5) at planting, in the form of triple superphosphate. Soybean was cropped in two seasons: 2010/2011 and 2011/2012. Soil samples were taken before soybean planting (after desiccation of Brachiaria) at 0.00-0.05 and 0.05-0.10 m for soil available P. Total weight of dry matter and P accumulated in ruzi grass were determined, as well as soybean yields, P in soybean grains, and P use efficiency (PUE). The use of natural phosphate increased soil P availability. The highest yields were obtained with higher application rates of triple superphosphate in the planting furrow combined with broadcast rock phosphate. Broadcast application of Arad reactive phosphate increases and maintains soil available P, and this practice, associated with ruzi grass grown as a cover crop and the use of triple superphosphate applied to soybean furrows, results in higher use of P by soybeans. © 2016, Revista Brasileira de Ciencia do Solo. All rights reserved.4

Nutritional requirements of sweet sorghum

The mineral requirements of two sorghum cultivars, Brandes and Rio, were studied both under field and greenhouse conditions. In the greenhouse plants received full strength Hoagland's solution, whereas in the field a uniform fertilization of 150 kg N/ha, 200 kg P2O5 and Kg K(2)0 was used. Under greenhouse conditions the need for nutrients obeyed the following decreasing order: K, N, Ca, Mg, P, S, Fe, Mh;, Cu and Zn. Export of nutrients in the grains, in percentage of total uptake was as follows, respectively for Brandes and Rio: N - 55 and 59, P - 41 and 43, K - 68 and 72, Ca - 16 and 10, Mg - 47 and 44, S - 47 and 60, Cu - 55 and 66, Fe-6 and 7, Mn - 10. and 8, Zn - 14 and 10. Date obtained with field grown plants plants showed that production of 1 ton of stalk required: 3.22 - 3.93 kg N, 0.40 - 0.45 P, 3.91 - 4.39 K, 1.09 - 0.77 Ca, 0.86 - 0.54 Mg, 0.32 - 0.41 S, 63 - 37 g Fe, 3-5 - 3.0 g Cu, 16 - 18 g Mn , 8-9 g Zn and 18 - 21 g B.As exigências nutricionais de dois cultivares de sorgo sacarino (Brandes e Rio) foram estudadas em condição de campo e em casa de vegetação com cultivo em solução nutritiva. O ensaio em casa de vegetação foi conduzido em bandejões de 40 1 de capacidade contendo solução nutritiva de Hoagland e Arnon, e no campo, foram amostradas plantas que receberam adubação com 150-200-100 kg/ha de N, P2O5 e K2O, respectivamente. A ordem decrescente de exigências em casa de vegetação foi: K, N, Ca, Mg, P, S e Fe, Mn, Cu, Zn. Considerando a colheita dos colmos e dos grãos, o cultivar Brandes exportou 55% do N, 41% do P, 68% do K, 16% do Ca, 38% do Mg, 47% do S, 6% do Fe, 55% do Cu, 10% do Mn e 14% do Zn absorvidos, e o cultivar Rio exportou 59% do N, 43% do P, 72% do K, 10% do Ca, 44% do Mg, 60% do S, 1% do Fe, 66% do Cu, 8% do Mn e 10% do Zn absorvidos, em casa de vegetação. Em condição de campo, as exigências para produzir 1 tonelada de colmo foram de 3,22 a 3,93 kg de N, de 0,40 a 0,45 kg de P, de 3,91 a 4,3i kg de K, de o,02 a 0,77 kg de Ca, de 0,86 a 0,54 kg de Mg; de 0,32 a 0,41 kg de S, de 68,82 a 36,71 g de Fe, de 3,48 a 2,94 kg de Cu, de 16,43 a 18,05 g de Mn, de 7,72 a 8,77 g de Zn e de 17,99 a 20,47g de B

Nitrogen washing from C3 and C4 cover grasses residues by rain

Crop species with the C4 photosynthetic pathway are more efficient in assimilating N than C3 plants, which results in different N amounts prone to be washed from its straw by rain water. Such differences may affect N recycling in agricultural systems where these species are grown as cover crops. In this experiment, phytomass production and N leaching from the straw of grasses with different photosynthetic pathways were studied in response to N application. Pearl millet (Pennisetum glaucum) and congo grass (Brachiaria ruziziensis) with the C4 photosynthetic pathway, and black oat (Avena Strigosa) and triticale (X Triticosecale), with the C3 photosynthetic pathway, were grown for 47 days. After determining dry matter yields and N and C contents, a 30 mm rainfall was simulated over 8 t ha-1 of dry matter of each plant residue and the leached amounts of ammonium and nitrate were determined. C4 grasses responded to higher fertilizer rates, whereas N contents in plant tissue were lower. The amount of N leached from C4 grass residues was lower, probably because the C/N ratio is higher and N is more tightly bound to organic compounds. When planning a crop rotation system it is important to take into account the difference in N release of different plant residues which may affect N nutrition of the subsequent crop