The effect of nitrogen fertilization on the release of soil nitrogen

Summary The effect of fertilizer nitrogen on the available amount of soil nitrogen was investigated in a greenhouse experiment. To 9 different soils, 0, 50, 100 and 200 kg N/ha were applied, resp., as (N¹⁵H₄)₂SO₄ with an atom excess N-15 of 1%.No priming effect could be found for any of the treatments. The available amount of soil N, expressed as A_N value, was not affected by rate of N-fertilizer application.     

On the importance of quantifying bioavailable nitrogen instead of total nitrogen

Monitored and modeled data provided the basis for the establishment of two nitrogen (N) budgets covering the Kattegat-Belt Sea area in the period 2000–2009: one for total nitrogen (TN) and one for bioavailable nitrogen (N_bio). Our results show a significant difference between the two budgets, and we argue that N_bio is more important than TN for our understanding of the sources causing marine eutrophication. Consequently, an optimal strategy for abatement of eutrophication aims at minimizing N_bio rather than TN. The TN budget shows that advection from the adjacent seas is the dominant source of N to the Kattegat-Belt Sea area. The loadings from land and atmosphere only account for 14 and 9 % of the TN loadings, respectively. However, when the bioavailability of the different N sources is taken into account, the supply from land and atmosphere becomes relatively more important, now accounting for 21 and 16 %, respectively (37 % in total). The ecological relevance of land and atmosphere loadings is most likely even larger since a fraction of the input from the Skagerrak is exported again before it can support primary production. Water action plans have reduced the direct loadings of TN from land and atmosphere by about 35 % since the 1980s. The contributions from land and atmosphere accounted for 47 % of the N_bio loadings in the 1980s. Hence, loadings from land and atmosphere have only decreased by 10 % points since the 1980s: from 47 to 37 %. The largest sink of TN in the study areas is advection to the adjacent seas (71 %) whereas denitrification and burial only accounts for 17 and 11 %, respectively.     

Changing nitrogen source on the yield and nitrogen content of soybeans

Summary Soybean plants were grown in nutrient culture solutions containing 150 ppm of N either as an equal concentration of NH₄ ⁺ or NO₃ ^–, or all NO₃ ^–. At the R2 stage of growth for some plants, the N form was changed to either all NO₃ ^– or all NH₄ ⁺, but at the same total N concentration as before. Highest seed yield was obtained with all NO₃ ^– over the entire growth period, the poorest when the N form was switched from an equal ratio of NH₄ ⁺ and NO₃ ^– to all NH₄ ⁺ at the R2 stage. Kjeldahl N concentrations in the plant leaves and seed were highest when NH₄ ⁺ was part or all of the N source in the nutrient solution. These results may partially explain why the literature is inconsistent on the effect of added fertilizer N on soybean seed yield, and may pose a problem in using leaf Kjeldahl N concentration to determine plant N sufficiency.     

The contribution of symbiotic nitrogen fixation to the nitrogen economy of natural ecosystems

Summary Fourty four species of native wild herbaceous legumes belonging to 12 genera and associated with mature fallow lands of the derived savanna were collected from seven random locations encompassing an estimated area of 10,800 km² and containing the seven different geomorphological soil formations in Anambra State of Nigeria.The number of legume species found differed according to the dominant grass in the fallows sampled, more species being associated with Andropogon, Hyperrhenia and Pennisetum than with Imperata and Loudetia. Detailed vegetation analysis of one hectare of fallow land dominated by Loudetia in one of the locations revealed that legumes comprised about 3% of the species encountered.In greenhouse trials, all the 19 species studied nodulated. The correlation (r=0.646) between fresh weight of nodules and dry weight of tops was significant at 0.01 level. Leaf N in these species ranged from 4.27% to 1.88%.The study indicated that a large number of naturally occurring herbaceous leguminous species, some of which appear to have promising potentials for increasing the N economy of the ecosystem, exists in the fallow land of the derived savanna.     

氮肥形态对冬小麦根际土壤氮素生理群活性及无机氮含量的影响

采用大田盆栽方法研究了硝态氮肥、铵态氮肥、酰胺态氮肥3种氮肥形态对冬小麦品种豫麦50生育中后期(拔节期、开花期、花后14 d、花后28 d)根际土壤氮转化相关微生物活性、酶活性和根际土壤NH+4离子、NO-3离子含量的影响。结果表明:随着生育期的推进,除脲酶外,氨化细菌、硝化细菌、亚硝化细菌、反硝化细菌和蛋白酶活性变化的均为"倒V"型变化特征,以花后14 d活性最强;而脲酶活性在拔节期最强,并且其活性远大于其它微生物及酶。氮肥形态对根际土壤氮素生理群及无机氮的影响不同。酰胺态氮肥促进了根际氨化细菌、反硝化细菌、脲酶、蛋白酶的活性,而硝化细菌、亚硝化细菌在硝态氮肥条件下活性较强。除拔节期外,土壤中NH+4离子在铵态氮肥处理下含量较高,NO-3离子在酰氨态氮肥处理下含量较高。因此,酰胺态氮能够促进小麦根际土壤有机氮的分解,硝态氮肥可以促进土壤中氨的转化,以利于小麦根系的吸收与利用。氮肥形态主要是通过影响土壤中氮素生理类群及酶的活性,从而影响土壤中无机氮的含量。     

香蕉苗期氮素亏缺与补偿对植株生长和根系形态的影响

为探究氮素亏缺及亏缺后补偿供氮对蕉苗生长及其根系形态特征的影响,该研究以主要栽培品种基因组类型(AAA型和ABB型)的香蕉品种为材料,通过石英砂基质培养结合氮素亏缺与补偿处理,分析其株高、叶长、叶宽、新增绿叶数、地上部和根系的鲜重和干物质质量、根长和根表面积及根体积等指标的变化。结果表明：(1)亏缺30 d,香蕉苗呈现明显的缺氮表型症状,株高、叶长、叶宽及新增绿叶数均显著降低,根系干物质积累增加,品种Ⅰ、Ⅱ根系干物质分别提高64.71%、87.50%,根冠比增加,总根表面积分别增加4.38%、11.85%,体积分别增加71.78%、66.55%。(2)亏缺68 d,干物质积累受到明显抑制,品种Ⅰ、Ⅱ全株干物质质量降低33.74%、42.04%,根系干物质质量与常规处理无显著差异,根系形态参数变化趋势与轻度亏缺一致。(3)亏缺后补偿供氮,缺氮症状消失,植株生长指标恢复正常水平;品种Ⅰ、Ⅱ根系干物质质量显著增加51.22%、52.38%,根冠比显著高于常规处理,根系趋向正常形态生长,并且总根体积分别增加61.80%、45.92%;轻度氮素亏缺后适时补偿供氮,缺氮蕉苗可恢复正常生长,根系干物...     

不同供氮量对二月兰产量、土壤无机氮残留及氮平衡的影响

研究华北冬绿肥二月兰对不同供氮水平的响应特征,确定实现绿肥高产高效的土壤适宜供氮量,可为华北集约化农田最大化发挥绿肥生态效应和优化春玉米/冬绿肥轮作体系氮素管理提供理论依据和技术参考.选取多年不施肥试验地设置供氮梯度试验,研究了不同供氮水平对冬绿肥二月兰翻压前地上部生物量累积、氮素吸收、土壤无机氮残留和冬绿肥季土壤氮素平衡的影响.结果表明: 在土壤无机氮含量较低(0～90 cm土层15 kg·hm^-2)条件下,施氮显著提高二月兰生物量和吸氮量.其中,施氮90 kg·hm^-2处理表现最高,绿肥生物量(干质量)和吸氮量分别为2031.0和42.0 kg·hm^-2;土壤无机氮残留量随施氮量增加而增加,且在施氮量高于60 kg·hm^-2后呈现快速增加趋势;随施氮量增加二月兰生长季的表观氮平衡表现出由亏缺到盈余的变化特征,在施氮量为60～90 kg·hm^-2条件下氮收支基本平衡.土壤供氮量(绿肥播前0～90 cm土壤无机氮含量与施氮量之和)与二月兰生物量、吸氮量和绿肥翻压前土壤无机氮含量的关系可以分别用二次、线性加平台和指数方程进行模拟,依据模型计算二月兰生物量最高值(2010 kg·hm^-2)时的播前土壤供氮量和绿肥翻压前土壤无机氮残留量分别是136和78 kg·hm^-2;而在二月兰吸氮量最高值40 kg·hm^-2时,二月兰生物量为1919 kg·hm^-2,相当于最高生物量的95%,绿肥翻压前土壤残留无机氮降低至57 kg·hm^-2,与之对应的播前土壤供氮量为105 kg·hm^-2,该值与目前华北地区优化施氮下玉米收获后土壤残留无机氮推荐含量(100 kg·hm^-2)基本相当.综合考虑绿肥的农学和环境效应,春玉米/冬绿肥轮作体系中二月兰播前土壤供氮量应控制在100～105 kg·hm^-2.     

The contribution of associative and symbiotic nitrogen fixation to the nitrogen nutrition of non-legumes

During the past 10 years estimates of N₂ fixation associated with sugar cane, forage grasses, cereals and actinorhizal plants grown in soil with and without addition of inoculum have been obtained using the ¹⁵N isotope dilution technique. These experiments are reviewed in this paper with the aim of determining the proportional and absolute contribution of N₂ fixation to the N nutrition of non-legumes, and its role as a source of N in agriculture. The review also identifies deficiencies in both the totality of data which are currently available and the experimental approaches used to quantify N₂ fixation associated with non-legumes.Field data indicate that associative N₂ fixation can potentially contribute agronomically-significant amounts of N (>30–40 kg N ha^-1 y^-1) to the N nutrition of plants of importance in tropical agriculture, including sugar cane (Saccharum sp.) and forage grasses (Panicum maximum, Brachiaria sp. and Leptochloa fusca) when grown in uninoculated, N-deficient soils. Marked variations in proportions of plant N derived from the atmosphere have been measured between species or cultivars within species.Limited pot-culture data indicate that rice can benefit naturally from associative N₂ fixation, and that inoculation responses due to N₂ fixation can occur. Wheat can also respond to inoculation but responses do not appear to be due to associative N₂ fixation. ¹⁵N dilution studies confirm that substantial amounts of N₂ can be fixed by actinorhizal plants.     

Total soil nitrogen and nitrogen mineralization

Summary The mineralization capacity of 24 different soils was determined from incubation experiments. Relatively rapid mineralization and nitrification was found with soils from cultivated land, and pastures, but soils under natural vegetative covers of conifers and hardwoods were mostly ammonifying. A close relationship could be established between the total nitrogen content of the soil and the amount of mineral nitrogen formed during incubation. Important connections could also be shown between the available nitrogen contents at different times during the incubation period; these suggest that the incubation period can be considerably shortened.     

长期氮添加对草甸草原生态系统氮库的影响

大气氮沉降增加深刻影响生态系统物种多样性、生产力及其稳定性,研究草原生态系统N库如何响应不断增加的大气氮沉降至关重要。本研究在内蒙古额尔古纳草甸草原开展刈割和不同水平外源氮添加试验,设置6个氮添加水平: 0、2、5、10、20和50 g·m^-2·a^-1,同时设置刈割处理,分为刈割和不刈割2个水平。在连续处理的第7年,采集群落中优势植物地上部分、群落根、地表凋落物和0～100 cm分层土壤样品,测定N含量并计算N库储量。结果表明: 氮添加显著增加植物地上部分和凋落物N含量,以及羊草、植物群落和凋落物的N库及生态系统N库总量。刈割处理显著增加羊草叶片和凋落物N含量,降低羊草、植物群落和凋落物N库,但并不改变它们对氮添加的响应格局。此外,刈割和氮添加对植物群落N库存在显著的交互作用。在不刈割处理下,高水平氮添加使更多的氮储存在凋落物中等待分解,植物群落N库的饱和阈值出现在10 g·m^-2·a^-1;在刈割处理下,植物群落N库表现为随氮添加量增加而不断增加,并且在相同水平氮添加条件下刈割后进入到植物群落N库中的氮更多。刈割可以缓解氮沉降不断增加对生物多样性和生态系统稳定性造成的不利影响,并可以在一定程度上推迟氮沉降增加引起的生态系统氮饱和的发生。     

掺混氮肥配施抑制剂对土壤氮库的调控作用

采用冬小麦盆栽试验,探讨掺混氮肥(缓释肥N∶普通尿素N=1∶1)配施氮肥抑制剂NAM对冬小麦土壤铵态氮、硝态氮、微生物生物量氮和固定态铵含量及小麦产量、氮肥利用率的影响,分析不同处理土壤矿质氮库、微生物生物量氮库和固定态铵库的动态变化特征.试验共设6个处理,不施氮肥(CK)、普通尿素(U)、掺混氮肥(MU)、MU+2.5‰NAM(MUN₁)、MU+5‰NAM(MUN₂)和MU+7.5‰NAM(MUN₃).结果表明:与MU处理相比,MUN₂和MUN₃处理推迟了NH₄⁺-N峰值出现的时间;小麦整个生长季,添加NAM处理的土壤矿质氮平均含量比MU处理下降了5.3%～11.7%;分蘖期至抽穗期,MU处理的微生物生物量氮矿化量和矿化率分别为38.96 mg·kg^-1和91.5%,均高于U处理,而MUN₁、MUN₂和MUN₃处理分别为58.73 mg·kg^-1和83.3%、94.20 mg·kg^-1和94.6%、104.46 mg·kg^-1和96.3%,添加NAM处理固定态铵的释放量比MU处理提高了2.83~9.19 mg·kg^-1.通径分析结果显示,与MU处理相比,添加NAM减弱了土壤NH₄⁺-N库对NO₃^--N库的直接影响,增强了固定态铵库通过影响NH₄⁺-N库对NO₃^--N库的间接作用.同时,MUN₁、MUN₂和MUN₃处理的小麦籽粒产量较MU处理分别提高了31.6%、21.5%和22.9%,氮肥利用率分别提高了8.1%、13.5%和3.1%.综上,配施NAM通过对氮素释放及在土壤中转化的双重调控,延迟土壤NH₄⁺-N峰值出现的时间及后续向NO₃^--N的转化,提高微生物生物量氮和固定态铵的供氮作用,从而提高了作物产量和氮肥利用率.     

Uptake of fertilizer nitrogen and soil nitrogen by rice using15N-labelled nitrogen fertilizer

Data from five field experiments using labelled nitrogen fertilizer were used to determine the relative effects of soil nitrogen and fertilizer nitrogen on rice yield. Yield of grain was closely correlated with total aboveground nitrogen uptake (soil+fertilizer), less closely correlated with soil nitrogen uptake and not significantly correlated with fertilizer nitrogen uptake. When yield increase rather than yield was correlated with fertilizer nitrogen uptake, the correlation coefficient was statistically significant.Contribution from the Laboratory for Flooded Soils and Sediments, Agronomy Dept., Louisiana Agri. Exper. Sta., Louisiana State Univ., Baton Rouge, LA 70803, and Univ. of Florida, Agricultural Research and Education Center, Sanford, FL 32771.     

Modelling and measuring the effect of nitrogen catch crops on the nitrogen supply for succeeding crops

Nitrogen catch crops are grown to absorb nitrogen from the rooting zone during autumn and winter. The uptake of N (N_upt) from the soil inorganic N pool (N_min) to a pool of catch crop nitrogen, will protect the nitrogen against leaching. After incorporation, a fraction (m) of the catch crop nitrogen is mineralized and becomes available again. However, not all available nitrogen present in the soil in the autumn is lost by leaching during winter. A fraction (r) of the nitrogen absorbed by the catch crop would, without a catch crop, have been retained within the rooting zone. The first year nitrogen beneficial effect (N_eff) of a catch crop may then be expressed b N _eff = m*N _upt - r* N _upt The soil-plant simulation model DAISY was evaluated for its ability to simulate the effects of catch crops on spring N_min and N_eff. Based on incubation studies, parameter values were assigned to a number of catch crop materials, and these parameter values were then used to simulate spring Nmin. The model was able to predict much of the vairiation in the measured spring Nmin (r² = 0.48***) and there was good agreement between the measured and the simulated effect of winter precipitation on spring N_min and Neff.Scenarios including variable soil and climate conditions, and variable root depth of the succeeding crop were simulated. It is illustrated that the effect of catch crops on nitrogen availability for the succeeding crop depends strongly on the rooting depth of the succeeding crop. If the succeeding crop is deep rooted and the leaching intensity is low, there is a high risk that a catch crop will have a negative effect on nitrogen availability. The simulations showed that the strategy for the growing of catch crops should be adapted to the actual situation, especially to the expected leaching intensity and to the rooting depth of the succeeding crop.     

An assessment of nitrogen fixation as a source of nitrogen to the North Atlantic Ocean

The role of nitrogen fixation in the nitrogen cycle of the North Atlantic basin was re-evaluated because recent estimates had indicated a far higher rate than previous reports. Examination of the available data on nitrogen fixation rates and abundance ofTrichodesmium, the major nitrogen fixing organism, leads to the conclusion that rates might be as high as 1.09 × 10¹² mol N yr^–1. Several geochemical arguments are reviewed that each require a large nitrogen source that is consistent with nitrogen fixation, but the current data, although limited, do not support a sufficiently high rate. However, recent measurements of the fixation rates per colony are higher than the historical average, suggesting that improved methodology may require a re-evaluation through further measurements. The paucity of temporally resolved data on both rates and abundance for the major areal extent of the tropical Atlantic, where aeolian inputs of iron may foster high fixation rates, represents another major gap.