Your search keyword '"Baranger, Edouard"' showing total 2 results

1. Diversifying cropping sequence reduces nitrogen leaching risks.

Author

Beillouin, Damien, Pelzer, Elise, Baranger, Edouard, Carrouée, Benoit, Cernay, Charles, de Chezelles, Emmanuel, Schneider, Anne, and Jeuffroy, Marie-Hélène

Subjects

*CROP rotation, *WINTER wheat, *CATCH crops, *SOIL mineralogy, *LEACHING, *CROP management, *LEGUMES

Abstract

• We monitored soil mineral N during various cropping sequences. • We simulated a 20-year series of N leaching for the cropping sequences. • We found an impact of the preceding cop on N leaching after the following crop. • Catch crop and oilseed rape volunteers reduced N leaching risk. • Diversified cropping sequences can reduce N leaching by up to 40 %. Overuse of chemical fertiliser in cereal cropping systems has resulted in severe degradation of air and water quality. Diversifying cropping sequence with legumes provides a natural source of nitrogen (N), but also increases N leaching risks after their growing period. Here, we hypothesize that legumes and other break crops, i.e., crops grown to diversify the cropping sequence, reduce N leaching at the rotation scale due to their contribution to increasing nutrient use efficiency and crop N recovery of the following cereal crops. In two 4-year experiments conducted in northern France, we monitored agronomic performance and the changes in the soil mineral N content at field scale in six preceding crop-current crop combinations including winter wheat (Triticum aestivum), pea (Pisum sativum L.) and oilseed rape (Brassica napus L.). We quantified N leaching after each crop as a function of the preceding crop with a water-fluxes model based on soil mineral N content, climate data and soil characteristics. We then simulated N leaching at the rotation scale, for 20 years of climate conditions and various cropping management systems. We show that growing pea or oilseed rape reduced soil mineral N content at harvest of the following cereals (up to mean values of −28 and −19 kg N ha−1 respectively), and N leaching risks during winter of the following cereals compared to the wheat-wheat cropping sequence. Although N leaching was higher during the winter after pea was cultivated, the cumulative losses over four experimental years of the pea cropping sequences were not significantly higher than the no-break cropping sequences. Over the 20 climate years, sequences including pea, oilseed rape, volunteers or catch crops reduced simulated N leaching by up to 40 % compared to wheat monoculture. Our study confirms that N leaching not only depends on the current crop but is also affected by the preceding crop. A large potential reduction in nitrogen leaching could be achieved in many intensive cereal-growing regions with very limited cropping sequence diversity. [ABSTRACT FROM AUTHOR]

Published

2021

2. Pea–wheat intercrops in low-input conditions combine high economic performances and low environmental impacts

Author

Pelzer, Elise, Bazot, Mathieu, Makowski, David, Corre-Hellou, Guénaëlle, Naudin, Christophe, Al Rifaï, Mehdi, Baranger, Edouard, Bedoussac, Laurent, Biarnès, Véronique, Boucheny, Patrick, Carrouée, Benoit, Dorvillez, Daniel, Foissy, Damien, Gaillard, Bernard, Guichard, Laurence, Mansard, Marie-Chantal, Omon, Bertrand, Prieur, Loïc, Yvergniaux, Morgane, and Justes, Eric

Subjects

*CATCH crops, *CROP yields, *ATMOSPHERIC nitrogen, *CROP quality, *EXPERIMENTAL agriculture, *NITROGEN fertilizers

Abstract

Abstract: Intensive agriculture ensures high yields but can cause serious environmental damages. The optimal use of soil and atmospheric sources of nitrogen in cereal–legume mixtures may allow farmers to maintain high production levels and good quality with low external N inputs, and could potentially decrease environmental impacts, particularly through a more efficient energy use. These potential advantages are presented in an overall assessment of cereal–legume systems, accounting for the agronomic, environmental, energetic, and economic performances. Based on a low-input experimental field network including 16 site-years, we found that yields of pea–wheat intercrops (about 4.5Mgha−1 whatever the amount of applied fertiliser) were higher than sole pea and close to conventionally managed wheat yields (5.4Mgha−1 on average), the intercrop requiring less than half of the nitrogen fertiliser per ton of grain compared to the sole wheat. The land equivalent ratio and a statistical analysis based on the Price''s equation showed that the crop mixture was more efficient than sole crops particularly under unfertilised situations. The estimated amount of energy consumed per ton of harvested grains was two to three times higher with conventionally managed wheat than with pea–wheat mixtures (fertilised or not). The intercrops allowed (i) maintaining wheat grain protein concentration and gross margin compared to wheat sole crop and (ii) increased the contribution of N2 fixation to total N accumulation of pea crop in the mixture compared to pea sole crop. They also led to a reduction of (i) pesticide use compared to sole crops and (ii) soil mineral nitrogen after harvest compared to pea sole crop. Our results demonstrate that pea–wheat intercropping is a promising way to produce cereal grains in an efficient, economically sustainable and environmentally friendly way. [Copyright &y& Elsevier]

Published

2012