Effect of nitrogen availability on dry matter production, nitrogen uptake and light interception of Brussels sprouts and leeks

Netherlands Journal of Agricultural Science Pub Date : 1996-03-01 DOI:10.18174/NJAS.V44I1.554

R. Booij, A. Kreuzer, A. Smit, A. Werf

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引用次数: 52

Abstract

In field experiments with Brussels sprouts (cv. Kundry) and leeks (cv. Arcona) on a sandy soil, DM production and N uptake during crop growth were studied at different N application rates. N fertilizer application rate affected DM production, leaf area expansion and N uptake more strongly in Brussels sprouts than in leeks. When all N was applied before transplanting, Brussels sprouts showed a higher recovery of N fertilizer than leeks. This was explained by a higher rate of DM production in Brussels sprouts, a consequence of faster leaf area expansion. Late N application, whether as a part of a split application or not, increased N uptake more than DM production, so that tissue N concentrations increased. The relationship between N uptake and DM production depended on N availability and crop growth stage, and if all N was applied before transplanting, the relationship could be described by an asymptotic function. Plant plasticity allowed 'luxury consumption' of N to take place when availability was ample and 'dilution' of N when shortages developed during later growth stages. This implied an increasing tissue N concentration with increasing N application and a decreasing N concentration with increasing age. To achieve near-maximum DM production at any time, tissue N concentration should be kept at 2.8-3.1% DW during the whole growing period for Brussels sprouts as well as for leeks. However, in Brussels sprouts a minimum concentration of 1.2-1.5% DW still allowed growth. In both crops N uptake increased linearly with LAI until maximum leaf area (LAI = 4-5) was reached and this relationship was not affected by N application rate or by experimental year. Irrespective of N application rate or species, 2.3 g above ground biomass per MJ intercepted radiation was produced. Therefore, measurement of radiation interception by the canopy can be used as a tool to estimate the N status of the crop.

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氮素有效性对抱子甘蓝和韭菜干物质生产、氮素吸收和光截获的影响

在球芽甘蓝的田间试验中。昆德里)和韭菜(cv。以沙质土壤为研究对象，研究了不同施氮量下作物生长过程中DM产量和氮素吸收。氮肥施用量对球芽甘蓝DM产量、叶面积扩大和氮素吸收的影响强于韭菜。移栽前全施氮时，抱子甘蓝的氮肥回收率高于韭菜。这可以解释为球芽甘蓝的DM产量更高，这是叶面积扩大更快的结果。后期施氮，无论是否作为分施的一部分，对氮素吸收的增加都大于DM的产生，从而使组织氮浓度增加。氮素吸收与DM产量的关系取决于氮素有效性和作物生长阶段，如果在移栽前全部施氮，则两者之间的关系可以用渐近函数来描述。植物的可塑性允许N在供应充足时发生“奢侈消费”，在生长后期出现短缺时发生“稀释”。这表明组织氮浓度随施氮量的增加而增加，随年龄的增加而降低。在球芽甘蓝和韭菜的整个生育期，组织氮浓度应保持在2.8-3.1%日重。然而，在球芽甘蓝中，最低浓度为1.2-1.5% DW仍然允许生长。两种作物的氮素吸收量均随叶面积(LAI = 4 ~ 5)的增加呈线性增长，且不受施氮量和试验年份的影响。无论施氮量或物种如何，每MJ拦截辐射产生2.3 g地上生物量。因此，测量冠层对辐射的截留可以作为估算作物氮素状况的工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Netherlands Journal of Agricultural Science

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