Effects of nitrate,ammonium and chloride application on the yield and nitrate content of soil-grown lettuce

Summary

The effect of nitrogen availability and nitrogen form on the yield and nitrate content of butterhead lettuce (Lactuca sativa var. capitata L.) grown in soil under greenhouse conditions was studied. The extent to which chloride application can reduce nitrate content by supplying the plant with an alternative osmotically active anion, and whether the presence of ammonium in the soil is a necessary prerequisite for an effect of chloride, was also examined. Reducing NO₃-N availability from 260 to 200 kg N ha^–1 significantly reduced nitrate content while head fresh weight was unaffected. Further reducing NO₃-N availability to 120 kg N ha^–1 significantly reduced both nitrate content and fresh weight. Substituting 40% of the available NO₃-N with NH₄-N significantly reduced nitrate content while fresh weight was unaffected. The effect of NH₄-N application on plant nitrate content was enhanced by the application of the nitrification inhibitor dicyandiamide (DCD). Despite increasing chloride uptake, the application of chloride had no significant effect on head fresh weight or nitrate content when available nitrogen was in the nitrate form irrespective of the level of nitrogen application. Chloride application similarly had no effect on head fresh weight or nitrate content when applied together with ammonium without the nitrification inhibitor DCD, despite a greater uptake of chloride. Where both ammonium and DCD were applied, however, chloride application significantly reduced head nitrate content.     

Effects of N fertilizers and rates on yield,safety and nutrients in processing spinach genotypes

Two field experiments were carried out at the Experimental Field, Department of Food Science (TE, Italy) in 2004 and 2005 to evaluate the effects of genotypes, different N forms and N rates on yield, safety and nutritional features of processing spinach. Experiment 1, as treatments, included spinach genotypes and N forms (CO(NH₂)₂; Agricote; NH₄NO₃); experiment 2 included three N forms (Ca(NO₃)₂; (NH₄)₂SO₄; NH₄NO₃) applied at rates of 0, 75, 150, 200 kg N ha⁻¹. This research work confirmed differences among spinach genotypes in terms of efficiency in N use and oxalate and nitrate accumulation. Spinach accumulated much more nitrate in petioles and much more oxalate in blades indicating that nitrate and oxalate might play a counterrole to each other. Fertilizers containing N under forms not readily available to the crop, i.e. Agricote, CO(NH₂)₂ and (NH₄)₂SO₄, increased nitrate and oxalate accumulations less than fast N-release fertilizers, but their effect on yield was limited. Highest yield with contents of nitrate and oxalate lower than the limits imposed to avoid health problems, were achieved with Ca(NO₃)₂, at rates of 130 and 150 kg N ha⁻¹ NH₄NO₃.     

番茄根系分泌物、木质部和韧皮部汁液组分对矿质氮、有机氮营养的响应

 采用营养液培探讨了番茄幼苗根系参数、根系分泌物、木质部和韧皮部汁液组分对矿质氮（NH₄⁺-N、NO₃^--N）和有机氮（Glycine）的不同响应。结果表明,不同氮素处理8 d后,'申粉918'、'沪樱932'番茄根系干质量、根系体积表现为NO₃^--N > Gly-N > 对照 > NH₄⁺-N处理;而根系活力则表现为以供Gly-N 或NO₃^--N为最高,其次为供NH₄⁺-N的处理,以对照处理为最低。不同氮素形态显著影响不同番茄品种根系分泌物、木质部和韧皮部各组分含量。 NO₃^--N处理的番茄根系分泌物、木质部和韧皮部汁液中的NO₃^--N和P含量最高,供Gly-N、NH₄⁺-N其次,对照最低;而供Gly-N、NH₄⁺-N时铵态氮、游离氨基酸、可溶性糖含量一般均高于处理NO₃^--N和对照。番茄根际吸收不同氮素对根际pH亦产生不同的影响,吸收NO₃^--N和Gly-N后,根际pH显著升高,而吸收NH₄⁺-N后则降低。根系分泌物可溶性蛋白含量的变化表现为NO₃^--N > Gly-N > NH₄⁺-N> 对照,而木质部、韧皮部可溶性蛋白含量的变化则表现为Gly-N > NO₃^--N> NH₄⁺-N > 对照。番茄幼苗不同品种间的差异性表现,与氮素形态有关,以根系活力为指标的基因型差异在供应NO₃^--N、NH₄⁺-N和Gly-N及对照时,'沪樱932' 的根系活力均显著（P<0.05）大于 '申粉918'。     

Effect of nitrogen form and radiation on growth and mineral concentration of two Brassica species

Three greenhouse experiments were carried out to determine the growth, yield, nitrate, total N and S concentration in shoots, and water uptake of hydroponically grown Brassica rapa L. subsp. nipposinica var. chinoleifera and Brassica juncea L. In each experiment, daily photosynthetically active radiation (PAR) level was 5.0 mol m⁻² (low), 6.8 mol m⁻² (medium) or 9.0 mol m⁻² (high). Plants were supplied with nutrient solutions having equal N concentrations of 11 mM in different forms: 100% NH₄, 50% NH₄ + 50% NO₃, and 100% NO₃. Nitrogen supplied as 100% NH₄ reduced fresh and dry shoot biomass, leaf area, and leaf number in both Brassica species, especially at low and medium PAR levels. In both Brassica species, S concentrations were highest, while nitrate concentrations were lowest in leaves of plants grown at N supplied as 100% NH₄. No differences in leaf nitrate concentrations were observed between 50% NH₄ + 50% NO₃ and 100% NO₃ treatments. Low and high PAR levels increased the nitrate concentrations and decreased the N/S ratio in leaves of both crops compared to medium PAR level. Fresh shoot biomass was maximized in Brassica rapa when PAR level was above the medium value and nitrate was supplied in the nutrient solution as NO₃ or as a mixture of 50% NO₃ and 50% NH₄. The highest fresh shoot biomass of Brassica juncea was observed in all nutrient solution treatments at high PAR level.     

Effects of shading and NO3:NH4 ratio on the yield,quality and N metabolism in strawberry

The effect of 50% shading and NO₃:NH₄ ratio (0:100, 75:25, 50:50, and 25:75) in the nutrient solution on growth, yield, quality and N metabolism in hydroponically grown strawberry (Fragaria × ananassa var Camarosa) was evaluated. Both fresh and dry weights of leaves were significantly lower when a high concentration of either NO₃ (100%) or NH₄ (75%) was the sole N source in the nutrient solution. In unshaded plants, increasing of both NH₄ and NO₃ ratio in the nutrient solution reduced photosynthetic (Pn) rate, however in shaded plants the reduction of Pn became more pronounced at a higher ratio of NH₄ in the nutrient solution. The yield in terms of fresh and dry weight of fruit per plant was significantly increased at the 75:25 and 50:50 (NO₃:NH₄) treatments. Fruit size was significantly affected by the treatments, so that the biggest fruits in both shaded and unshaded plants were obtained under the 75:25 and 50:50 (NO₃:NH₄) treatments. Total soluble solid (TSS) in unshaded plants was increased with increasing NH₄ ratio in the nutrient solution, however in shaded plants it was reduced at high NH₄ ratio in the nutrient solution. In both shaded and unshaded plants, higher concentration of NH₄ significantly reduced the post-harvest life of the fruits. The increase of tissue N concentration was nearly proportional to the NH₄ concentration in the nutrient solution. The activity of nitrate reductase (NR) was increased by increasing NH₄ from 0 to 50% and then reduced at a higher ratio of NH₄ in the solution. Shading increased NH₄ concentration so that the shaded plant had nearly twice as high NH₄ concentration in the leaves. The increase of NH₄ concentration induced by shading could be partially the reduction of NH₄ assimilate because of the shortage of carbohydrate.     

Effects of source,rate, and frequency of N application on yield,marketable grades and rot incidence of sweet onion (Allium cepa L. cv. Granex-33)

In a field experiment in the 1988-89 season, fertilizer formulations of NH₄NO₃, Ca(NO₃)₂, NaNO₃, NaKNO₃, and KNO₃ as N sources were applied at 84 and 168 kg N ha^?1 to onion plots direct seeded in the fall. A second experiment in the 1990-91 season tested the same N sources, except KNO₃, at rates of 168 and 224 kg ha^?1. Application strategy involved both splitting the total amount of fertilizer over two periods of the growing season (October–December and January—April) and the application frequency. With medium and high application rates (168 and 224 kg ha^?1), NH₄NO₃, NaNO₃, and NaKNO₃, increased high-value jumbo and large onions (premium marketable grade). Increased premium grades was due to increased bulb size and weight. Only NH₄NO₃ and Ca (NO₃)₂ increased total onion weight when N rate was increased from 84 to 168 kg ha^?1. Less frequent applications of split amounts of 84 kg N ha^?1 reduced marketable weight in the 1988–89 season, but doubling the rate to 168 kg ha^?1 restored the higher yields. At 224 kg N ha^?1 in the 1990–91 season, differences in onion grades were more pronounced among the different N sources, and NH4 NO₃ was superior in producing jumbo and large size onions. High N rates (224 kg ha^?1) and more frequent applications of split portions also increased the weight of jumbo onions. Split applications, providing 33% of the total N in the first 12 weeks of the growth period plus three applications of 22% each in the second 12 week period, increased bulb size and maximized yield of premium marketable grades. Effect of N rate on onion rot was dependent on split methods of applying the N during early and late growth periods. However, reduction in onion rot by the split application strategy was dependent on N source. Bulb decay was highest with NH4NO₃ and least with Ca(NO₃)₂ and NaNO₃.     

In vitro studies of controlling tomato puffiness enhanced by temperature,nitrogen source and sucrose concetration

Tomato puffiness, which occurs after auxin spray under field conditions, was investigated by using the in vitro fruit-culture technique. Tomato flowers were cultured in different media or at different temperatures for 3 days, to induce parthenocarpy, with 2-hydroxymethyl, 4-chlorophenoxyacetic acid (HCPA) and then parthenocarpic fruits were transferred to media free of HCPA.The higher the temperature during induction of parthenocarpy, the higher the degree of puffiness. Puffiness enhanced at 30°C was corrected by succinic acid-2, 2-dimethylhydrazide (SADH), which lowered the auxin level.High ratio of NO₃-N : NH₄-N in the medium increased the degree of puffiness. Puffiness was enhanced in the medium with NO₃-N alone as the nitrogen source was corrected by (SADH) and by [2-chloroethyl]trimethylammonium chloride (CCC). Different nitrogen levels with a constant ratio of NO₃-N to NH₄-N did not affect the degree of puffiness.High concentrations of sucrose (6 and 8%) in the medium considerably increased the degree of puffiness, but this could also be corrected by CCC and SADH.     

氮素形态对白菜硝酸盐累积和养分吸收的影响

 试验研究表明, 白菜生长适宜营养液的NH^₄+-N 和NO₃^--N (mmol/L) 配比为5∶5, 随着NH^₄+-N比例的增加和收获时期的延迟, 白菜中硝酸盐积累减少, 而游离铵含量增加, NH^₄+-N比例超过75 %时叶片中脯氨酸明显积累, 生长速率下降, 叶片含水率、根长都明显下降, 根系吸收P、K、Ca、Mg 等元素降低,白菜氨害明显。调节适宜的氮素形态比例, 有利于白菜生长和品质提高以及对水分和养分的吸收利用。     

不同铵硝配比对芥蓝伤流液组分及植株氮磷钾积累的影响

采用伤流液组分分析和植物营养分析的方法,探讨了不同铵硝配比（CK,0∶100;T1,10∶90;T2,25∶75;T3,50∶50）影响芥蓝生长的生理机制。结果表明：与全硝态氮营养液对照相比,3 个营养液增铵处理均提高了芥蓝植株的生物量和伤流强度,其中营养液增铵25%（T2）处理的效果最好。T1 处理芥蓝植株伤流液中蛋白态氮和P 的流量与CK 相比显著增加;T2 处理芥蓝植株伤流液中NO₃^--N、P、K 流量均为最高;T3 处理芥蓝植株伤流液中NH₄⁺-N、氨基酸态氮和蛋
白态氮流量最高,而NO₃^--N 和K 流量则显著低于CK。T1 处理和T2 处理显著提高了芥蓝植株N、P、K 的含量和积累量;T3 处理亦显著提高了芥蓝植株N、P 的含量和积累量,但显著降低了K 的含量和积累量。综合来看,营养液适量增铵（25%）处理的效果最好,可以提高芥蓝根系吸收能力,促进氮代谢,增加植株对N、P、K 的吸收和积累,从而促进植株生长。     

Nutrient solution effects on the development and yield of Anthurium andreanum Lind. in tropical soilless conditions

The fertilization of anthurium grown in soilless culture in tropical countries is often empirically based. The methods used generally lead the grower to overestimate plant needs and to apply excessive quantities of nutrients. Mineral elements, and thus money, are wasted and there is a risk of pollution of groundwater and watercourses. In order to improve our knowledge of plant requirements, we measured, over 2 1/2 years, the growth and yield of anthurium plants receiving nutrient solutions with different total nitrogen, potassium and calcium concentrations and different NH₄⁺/NO₃⁻ ratios. Mineral analyses of plant parts, of nutrient, leachate and substrate solutions and of the solid substrate were carried out throughout plant development. Plants receiving 4.5 mmol N/l and 1.6 mmol K/l in the nutrient solution had significantly slower growth and lower yield compared to those receiving 8.9 mmol N/l and 3.2 mmol K/l. For these latter N and K concentrations, a N–NH₄⁺/N–NO₃⁻ ratio of 0.37 and a calcium concentration of 1.15 mmol/l gave better plant growth, development and yield than a ratio of 0.24 and a calcium concentration of 2.25 mmol/l. Applying the nutrient solution containing 8.9 mmol N/l and 3.2 mmol K/l with a N–NH₄⁺/N–NO₃⁻ ratio of 0.37 resulted in a shorter vegetative period and more and larger flower production. The calculated mineral balances of the crop showed that more than 60% of the supplied nutrients were lost in the leachate. Suitable nutrient solutions are proposed in order to match plant absorption at different crop growth stages. The volume of nutrient solution supplied can be reduced to limit the amount of leachate, but as water demand is high, there must be at least 30% of leaching to avoid salt accumulation in the substrate. Adjusting the nutrient solution volume and composition to match plant requirements is the first step for flower yield improvement, fertilizer efficiency and reduction of pollution.     

The effects of pre-sowing seed treatments on the germination and emergence of lettuce seeds at high salt concentrations

Radicle emergence in lettuce seeds cultivar ‘Hilde’ was reduced by NH₄NO₃ above 8×10^?2M, while radicle extension was inhibited by 8×10^?2M NH₄NO₃ and no seedlings emerged. Inhibition of radicle emergence by 8 and 16×10^?2M NH₄NO₃ was prevented by soaking seeds for 4 h before sowing in a mixture of $\text{GA}{}_{\mathrm{<mtext>4</mtext><mtext>7</mtext>}}$ and kinetin+phosphate buffer, and was partially prevented by soaking them for 4 h before sowing in phosphate buffer. These treatments did not prevent inhibition of radicle emergence by 32×10^?2M NH₄NO₃, but seeds soaked in growth regulators or phosphate buffer before sowing and taken from this NH₄NO₃ solution after 7 days and washed to remove excess salt gave 45–52% germination compared with 12 % for untreated seeds. Pre-treatment of the seeds did not prevent the inhibitory effect of NH₄NO₃ on radicle extension. In field experiments seeds treated with growth regulators + phosphate buffer or phosphate buffer alone gave a higher final percentage emergence from soils given 125 kg N/ha than did untreated seeds.     

Effects of NH4:NO3:urea ratio on cut roses yield, leaf nutrients content and proton efflux by roots in closed hydroponic system

The effects of the NH₄:NO₃ ratio in replenishment solution on Rosa L. flower yield and the impact of NH₄ substitution by urea on plant performance and on solution EC and pH have not been studied previously in closed (no leaching) hydroponic systems. A greenhouse experiment with six NH₄:NO₃:urea ratios (0:100:0, 12:88:0, 25:75:0, 50:50:0, 100:0:0 and 0:50:50) and two harvest cycles (winter and spring) was carried out to investigate these relationships. In winter, total and >40 cm cut flower yields were maximal in treatment 25:75:0. At lower NH₄ percentages (12.5:87.5:0 and 0:100:0), growth container solution pH varied between 7.8 and 8.5, reducing P, Ca and Mn concentration in leaves and increasing dry matter allocated to them. At higher NH₄ percentages, Ca uptake was inhibited, solution pH reached 3, and %P in leaves increased. Consequently, reducing sugars concentration in leaves increased and sucrose and starch concentrations decreased. A stepwise regression analysis indicated that the optimal NH₄:NO₃ ratio in feed solution is 40:60, with resulting solution pH of 5.9 in the growth container. In spring the maximum yield was obtained in treatment 0:50:50 and it exceeded the winter yield despite a higher solution EC (4.3 dS m⁻¹ vs. 3.5 dS m⁻¹ at harvest). The beneficial effect of urea (0:50:50 vs. 50:50:0) stemmed from the relatively lower NH₄ concentration in solution, that alleviated the NH₄–Ca uptake competition, and higher pH. The slope of the straight line relating [H⁺ efflux rate] to [NH₄⁺ uptake rate] in treatments 25:75:0, 50:50:0 and 100:0:0 was 0.44 mol H⁺/mol NH₄. In all other treatments the proton efflux was negligible.     

Nitrogen fertilization under saline conditions in tomato and cucumber plants

Summary

Tomato (Lycopersicon esculentum, Mill.) and cucumber (Cucumis sativus, L.) seedlings were grown in a growth chamber in 4 litre containers filled with nutrient solutions. Four experiments were conducted with four NaCl levels factorially combined with four N levels. The concentrations of NaCl were 4, 25, 50, and 100 mmol l^?1 and 4, 16, 32, and 64 mmol l^?1 in the tomato and cucumber experiments respectively. The N levels in allexperiments were 2, 6, 10 and 15 mmol l^?1 added as NO₃^? or as NH₄⁺ + NO₃^? (2:1). Salinity had a statistically significant negative effect on all responses considered, although the effect was N source-dependent. Addition of N enhanced development of shoot and root dry weights of both species. The optimum N concentration in the nutrient solution varied between 6 and 10 mmol l^?1, although the most appropriate N fertilizer varied with species. Leaf Cl^? concentration decreased in both species when NO₃^? was used as the N source, whereas it increased in the comparative tissues of plants fed with NH₄⁺ + NO₃^?. The effect of treatments on the other nutrients show effects of excess of NaCl, as the form of N source interferes with the uptake of essential nutrients which may cause nutritional disorders.     

Comparative effects of ultrasonic transducers on medium chemical content in a nutrient mist plant bioreactor

The objectives of this study were to evaluate the efficiency of ultrasonic transducers in a nutrient mist bioreactor by analyzing the chemical constituents (carbohydrates and inorganic elements) of the mists produced by ultrasonic transducers from a liquid sucrose-supplemented Murashige and Skoog (MS) medium. The ultrasonic transducer oscillation frequency with an input power of 2.8 MHz and at 17.5 W was the optimum condition since the contents of glucose, sucrose, total soluble carbohydrate, macro-elements (NH₄⁺-N, NO₃⁻-N, P, K, Mg, Ca and S), micro-elements (Na, Fe, Mn, Zn, B, I, Mo and Co), and pH value were similar to those in the MS medium after autoclaving. Further, when MS medium was replaced by Gamborg et al. medium (B-5) or woody plant medium (WPM) in this bioreactor at the same transducer settings, the NH₄⁺-N and NO₃⁻-N contents in nutrient mist generated were also similar to those in B5 or WPM after autoclaving, respectively. The results of this research represent a significant contribution towards development of a functional nutrient mist bioreactor.     

Responses of cucumber plant to NH4 and NO3 nutrition: The relative addition rate technique vs. cultivation at constant nitrogen concentration

Different N sources (NO₃⁻, NH₄⁺, or NH₄NO₃) at different relative addition rates (RAR) were supplied to cucumber (Cucumis sativus L.), a species sensitive to NH₄⁺ toxicity. For comparison, cucumber plants were also grown at constant concentrations of 1 and 5 mM NH₄⁺ or 5 mM NO₃⁻. The fresh weight of NH₄⁺-fed plants at RAR 0.15 and RAR 0.25 day⁻¹ was similar to that of NO₃⁻-fed plants, while at RAR 0.35 or RAR 0.45 day⁻¹ growth reduction occurred. When available as a constant concentration, NH₄⁺ decreased plant growth at 5 mM. It is concluded that at low rates of N supply the relative addition rate technique can be used for growing cucumber plants with NH₄⁺ as sole N source without deleterious effects.     

The effect of various nitrogen fertilization and foliar nutrition regimes on the concentrations of nitrates,ammonium ions,dry matter and N-total in carrot (Daucus carota L.) roots

Two field experiments (Experiment I in 2003–2005 and Experiment II in 2004–2005) with carrot c.v. ‘Kazan F₁’ were conducted at Trzciana village (50°06′N, 21°85′E). The experiments were arranged in a split-plot design with four replications. Two sub-blocks were identified in both experiments: I, without foliar nutrition; II, receiving plant foliar nutrition. The plants were sprayed three times alternately with: 2% urea solution, 1% solution of multi-component ‘Supervit R’ fertilizer (produced by Intermag, Poland) and again with 2% urea solution. Combinations with diversified nitrogen fertilization were distinguished within both sub-blocks. Experiment I comprised of: (1) Control, (2) Ca(NO₃)₂ 70, (3) Ca(NO₃)₂ 70 + 70, (4) (NH₄)₂SO₄ 70 and (5) (NH₄)₂SO₄ 70 + 70. Experiment II included: (1) Control, (2) ENTEC-26 35 + 35, (3) ENTEC-26 70 + 70, (4) ENTEC 26 105 + 105, (5) NH₄NO₃ 35 + 35, (6) NH₄NO₃ 70 + 70, (7) NH₄NO₃ 105 + 105. Where 70 kg N ha⁻¹ was used before sowing, whereas 35 + 35, 70 + 70 and 105 + 105 kg N ha⁻¹ were applied before sowing and as top dressing. Solid nitrogen fertilizer was added to the soil (produced by): Ca(NO₃)₂, Yara International ASA (Hydro); (NH₄)₂SO₄, Zak?ady Azotowe in Tarnów, Poland; NH₄NO₃, Zak?ady Azotowe in Pu?awy, Poland; and ENTEC-26, COMPO GmbH & Co. KG, Germany. The research aimed at determining the effect of diversified nitrogen fertilization and foliar nutrition on NO₃⁻, NH₄⁺, N-total and dry matter (d.m.) concentrations in carrot, and N uptake by storage roots. In Experiment I, nitrogen fertilization did not affect NO₃⁻ concentration, whereas in Experiment II, the applied N treatment increased NO₃⁻ concentration in carrot in relation to the control, except for the storage roots of plants fertilized with ENTEC-26 35 + 35. Nitrogen fertilization applied in both experiments caused a significant increase in N-total concentration in carrot and N uptake by storage roots in comparison with the control plants. In both experiments, nitrogen fertilization had a different effect on the concentrations of NH₄⁺ and d.m. in carrot. What is more, foliar nutrition treatments in both experiments had a different effect on the concentrations on NO₃⁻, N-total, d.m. in carrot and N uptake by carrot storage roots.     

应用BaPS技术研究双氰胺及硫对苹果园土壤尿素的硝化抑制效应

 在大田条件下应用气压过程分离法（BaPS）研究了双氰胺（DCD）和双氰胺与硫配合施用（DCD + S）对苹果园土壤氮素的硝化抑制效应。结果表明：施肥后40 d内,N + DCD和N + DCD + S处理的土壤NH₄⁺-N含量均高于N处理（对照）。N + DCD处理在6 ~ 20 d显著高于N处理;N + DCD + S处理直到30 d时仍显著高于N处理,比只施DCD的处理硝化抑制作用延长了10 d。两个添加硝化抑制剂处理土壤NO₃^--N含量显著低于N处理,降幅达18.72% ~ 58.91%。与N处理（对照）相比,N + DCD和N + DCD + S处理明显降低了土壤总硝化速率和反硝化速率,试验前期差异最大,进一步证实了硝化抑制剂可以有效地抑制NH4+-N向NO₃^--N的转化。     

Evaluating foliar nitrogen compounds as indicators of nitrogen status in Prunus persica trees

Mobile nitrogen (N) forms may be better N indicators of the N status of trees than total nitrogen (TN) due to their higher sensitivity to increasing N supply. A field experiment was carried out over a 3-year period to compare foliar concentrations of total N (TN), soluble N (SN), chlorophyll (Minolta SPAD readings), NH₄–N and NO₃–N as indicators of soil N availability in nectarine, Prunus persica L. Batsch, cv. ‘Fantasia’ (grafted on ‘Nemaguard’ peach, P. persica × P. davidiana) trees. Young trees were exposed to a range of fertilizer-N application rates. Based on correlation analysis, the best association between leaf N compounds with soil N supply and trunk diameter and/or fruit yield was obtained with TN and chlorophyll SPAD readings. Leaf concentrations of mobile N compounds (NH₄–N and NO₃–N) increased more than any other N compound under high N supply; however, their inconsistency among years and low leaf concentration difficult their use as N indicators. The optimum foliar TN for growth decreased with tree age, 4.4%, 3.6% and 3.3% in non-bearing 1-year-old trees, non-bearing 2-year-old trees and 3.3 fruit-bearing 3-year-old trees. The optimum SPAD readings were 40 in 2-year-old trees and 42 in 3-year-old trees. Stable N compounds (TN and chlorophyll SPAD) could be used to N diagnosis in the zone of N deficiency, and soluble N compounds (NH₄–N and NO₃–N) to diagnoses N excess.     

不同形态氮素营养对大白菜芝麻状斑点病发生的影响

 选择高感“大白菜芝麻状斑点病”品系03B9大白菜为试材,调查不同形态氮素营养对其发病的影响;并选择高抗品系C24、P8-1和高感品系03B9、P8-2为试材,在总氮素浓度为25 mmol · L-1,NO3- -N︰NH4+ -N分别为3︰7、5︰5和7︰3的水培条件下,研究氮代谢和抗氧化系统生理指标的变化。结果表明：铵态氮促进芝麻状斑点病发生的作用高于硝态氮和酰胺态氮。随铵态氮比例的增大,感病品系03B9和P8-2较抗病品系病斑数显著增多,叶柄中PPO活性和铵态氮、MDA含量及电导率升高,NR活性和多酚含量降低;抗病品系C24和P8-1叶柄中GDH活性和多酚含量升高,PPO活性、MDA含量及电导率变化不明显。推测营养液中铵态氮的比例增加,影响感病品系氮素代谢中有关酶类的活性,使体内铵态氮过量积累,导致细胞膜系统受到伤害,使液泡内的酚类物质与细胞质中的多酚氧化酶接触,引起褐变,在叶柄表面表现出芝麻斑点症状。     

A rapid nitrate sap test for outdoor tomatoes

Trials were conducted with tomatoes over 2 years to evaluate nitrate sap testing and determine desirable sap nitrate values. In addition, desirable values for acetic acid extractable nitrate-N (HOAc-NO₃-N) and total N were determined. There were strong linear correlations between applied N and sap nitrate-N, HOAc-NO₃-N, and to a lesser extent with total N. The desirable sap nitrate value at 6 weeks from transplanting was 880–1180 mg 1^?1 in the first year and 980–1120 mg l^?1 in the second year. The sap nitrate desirable values were generally lower later in the crop growth. The desirable values found in this study for HOAc-NO₃-N and total N were in good agreement with other published data.