Abstract
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.
Highlights
One of the most important aspects to consider when choosing cover crop species is the N accumulation capacity, either by atmospheric N2 fixation or uptake from soil, or both
For grasses grown as cover crops the capacity to accumulate N is as essential as the speed at which N contained in plant residues is washed back to the soil with rains or mineralized after desiccation, which will determine when this N will be available for the following crop
N supply to the subsequent crop may vary in each crop rotation system, which should be taken into account in the plant residue management
Summary
One of the most important aspects to consider when choosing cover crop species is the N accumulation capacity, either by atmospheric N2 fixation or uptake from soil, or both. The use of cover crops may result in significant increases in surface mulch and soil organic matter contents and in nutrient cycling (Rosolem et al, 2006). Some grasses have the C3 photosynthetic pathway for C fixation, e.g. black oat (Avena strigosa), while others show the C4 photosynthetic pathway, such as pearl millet (Pennisetum glaucum). This physiological discrimination influences N-release dynamics from the phytomass after the plants are cut (Rosolem et al, 2005). The use of cover crops may result in significant increases in surface mulch and soil organic matter contents and in nutrient cycling (Cantarella et al, 1997). The proportion of N that will be used by the subsequent crop will depend on the synchronization between N release from the straw and the demand of the succeeding crop
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