控释肥对夏玉米产量及田间氨挥发和氮素利用率的影响

在大田条件下研究了树脂包膜控释肥（CRF）和硫包膜控释肥（SCF）对夏玉米产量、田间氨挥发及氮肥利用率的影响.结果表明：控释肥能显著提高玉米产量.在相同施肥量（N、P、K量相同）情况下,全量控释肥CRF(1428 kg·hm^-2)和SCF（1668 kg·hm^-2）分别比全量普通复合肥CCF（1260 kg·hm^-2）增产13.15%和14.15%;控释肥施肥量减少25%（CRF 1071 kg·hm^-2;SCF 1251 kg·hm^-2）时,分别比CCF增产9.69%和10.04%;控释肥施肥量减少50%时（CRF 714 kg·hm^-2;SCF 834 kg·hm^-2）,其产量与CCF无显著差异.对夏玉米田间土壤原位氨挥发进行研究表明,控释肥处理氨挥发速率上升缓慢,最大挥发高峰出现时间比普通肥处理晚7 d,土壤氨挥发量在0.78～4.43 kg N·hm^-2,比普通肥处理(9.11 kg N·hm^-2)减少51.34%～91.34%.控释肥的氮肥利用率和农学效率也均显著高于普通肥处理.     

Total antioxidant capacity (TAC): is it an effective method to evaluate the oxidative stress in uraemia?

Lipoprotein abnormalities are common in uraemia and are considered important factors for development of atherosclerosis and progression of renal disease. Reduction of total antioxidant capacity (TAC) and lipid peroxidation (LP) probably play a major role in both processes. The aim of this study was to assess the effect of renal function, dietary manipulation and lipids on TAC of uraemic patients with different chronic renal failure (CRF). Sixty patients (36M, 24F), aged 60 ± 12 years were divided into five groups according to serum creatinine levels (sCr, mg/dl)— CRFI, 1.5–3; CRFII, > 3–5.5; CRFIII, > 5.5; CRFIV, > 3 on vegetarian supplemented diet (SD); CRFV haemodialysis patients (HD)-and investigated for TAC by enhanced chemiluminescent assay, autoantibodies against oxidized LDL (oxLDLAb), lipids, apolipoprotein AI, B, Lp(a) and uric acid (UA). The results were compared to a control group of 19 people (8M, 11F), aged 52 ± 11 years with sCr < 1.5. TAC increased significantly with the progression of CRF and was strongly related to both sCr and UA. Lipids and SD did not show any influence on TAC. Unexpectedly, lipid peroxidation did not correlate to TAC, neither to sCr or UA. HD accounted for a mild reduction of both TAC and LP. Patients on SD showed a marked reduction of LP as compared to patients with a similar degree of renal failure (CRF-III) but on conventional diet. Our results suggest that elevated TAC in uraemia is likely to be dependent on increased UA levels and does not seem to induce an effective protection in vivo from oxidative stress. In conclusion, TAC does not appear to be a reliable method for assessing the oxidative susceptibility of CRF patients. © 1998 John Wiley & Sons, Ltd.     

不同硝化抑制剂对红壤氮素硝化作用及玉米产量和氮素利用率的影响

本研究分析添加不同种硝化抑制剂及其组合的高效稳定性氯化铵氮肥对红壤硝化作用、玉米产量和氮肥利用率的影响,旨在筛选出适合酸性红壤的高效稳定性氯化铵态氮肥。在氯化铵中分别添加硝化抑制剂2-氯-6-三甲基吡啶(CP)、3,4-二甲基吡唑磷酸盐(DMPP)和双氰胺(DCD)及其组合,制成6种高效稳定性氯化铵态氮肥,以不施氮肥(CK)和施氯化铵(N)为对照,进行等氮量玉米盆栽试验。结果表明: 与N处理相比,CP+DMPP和DMPP+DCD处理红壤中铵态氮含量提高56%～62%,显著高于CP、DMPP和DCD处理;土壤表观硝化率显著降低33%～34%。添加硝化抑制剂及其组合的6个处理均显著提高了玉米生物量和氮肥吸收利用率。与N处理相比,单独添加硝化抑制剂处理生物量均显著高于硝化抑制剂组合处理,平均提高1.3倍;添加DCD处理效果最显著,玉米籽粒产量、吸氮量和氮肥吸收利用率分别显著提高4.1、6.3和4.4倍。为了达到既能低成本又能提高产量和氮肥利用率的效果,在红壤上添加硝化抑制剂DCD是最佳选择。     

A Large and Deep Root System Underlies High Nitrogen-Use Efficiency in Maize Production

Excessive N fertilization results in low N-use efficiency (NUE) without any yield benefits and can have profound, long-term environmental consequences including soil acidification, N leaching and increased production of greenhouse gases. Improving NUE in crop production has been a longstanding, worldwide challenge. A crucial strategy to improve NUE is to enhance N uptake by roots. Taking maize as a model crop, we have compared root dry weight (RDW), root/shoot biomass ratio (R/S), and NUE of maize grown in the field in China and in western countries using data from 106 studies published since 1959. Detailed analysis revealed that the differences in the RDW and R/S of maize at silking in China and the western countries were not derived from variations in climate, geography, and stress factors. Instead, NUE was positively correlated with R/S and RDW; R/S and NUE of maize varieties grown in western countries were significantly greater than those grown in China. We then testified this conclusion by conducting field trials with representative maize hybrids in China (ZD958 and XY335) and the US (P32D79). We found that US P32D79 had a better root architecture for increased N uptake and removed more mineral N than Chinese cultivars from the 0-60 cm soil profile. Reported data and our field results demonstrate that a large and deep root, with an appropriate architecture and higher stress tolerance (higher plant density, drought and N deficiency), underlies high NUE in maize production. We recommend breeding for these traits to reduce the N-fertilizer use and thus N-leaching in maize production and paying more attention to increase tolerance to stresses in China.     

Proof of concept: nitrogen use efficiency of contrasting spring wheat varieties grown in greenhouse and field

Aims

Major aims were to test and evaluate a new concept for assessment of nitrogen use efficiency (NUE) of crops by growing six spring wheat varieties in greenhouse and field environments. NUE was calculated with a plant based concept integrating the entire crop life history and separating plant characteristics from environmental factors affecting NUE. Specific hypotheses were tested related to the varieties’ drought and nutrient fertilisation responses for NUE components, and coherence of those responses in field and greenhouse.

Methods

The wheat (Triticum aestivum L.) cultivated varieties ‘Diskett’, ‘Granary’, ‘Quarna’, ‘Stilett’, ‘Vinjett’, and a Swedish landrace (‘Dala’) were grown in field and greenhouse environments in Central Sweden. Two fertilisation treatments were included in a field and greenhouse experiment, and in the greenhouse also drought. The NUE components N uptake efficiency (U_N), grain-specific N efficiency (E_N,g) and grain N concentration (C_N,g) were assessed.

Results

Drought reduced yield and NUE through E_N,g, and more so when drought occurred prior to anthesis than after anthesis. Effect of fertilisation treatment on NUE components was similar in the two set-ups, but there were fewer variety × fertilisation interactions in the field. U_N was higher in the field and E_N,g was higher in the greenhouse, while C_N,g and overall NUE were similar in the two environments. Ranking of varieties regarding NUE and U_N was similar in the greenhouse and field, but different regarding E_N,g and C_N,g.

Conclusions

The NUE concept is a useful tool to describe and integrate important NUE components for crops grown in different treatments (nutrient fertilisation, drought) and experimental set-ups, i.e. greenhouse and field. Similar variety ranking in overall NUE across experimental set-ups indicates stable results in different environments.     

Effect of decreasing dietary crude protein in fattening calves on the emission of ammonia and greenhouse gases from manure stored under aerobic and anaerobic conditions

Dietary strategies can potentially help to reduce nitrogen (N) emissions and decrease the environmental impact of beef production. This study aimed to evaluate the effects of dietary crude protein (CP) concentration on animal performance, N excretion, and manure N volatilisation of finishing Holstein animals. In a first study, 105 Holstein bulls (BW 344 ± 2.6 kg; age 252 ± 0.9 days) were allocated to eight pens to evaluate the effect of two treatments (medium (M) and low (L), which contained CP 14.5% and 12% on a DM basis, respectively) on performance, and results confirmed that dietary CP decrease did not impair animal growth. In a second study, N excretion study, 24 Holstein heifers (BW 310 ± 5.3 kg; age 251 ± 1.4 days) were distributed randomly depending on the initial BW to three treatments (high (H), M, and L, which contained CP 17%, 14.5% and 12% on a DM basis, respectively). Based on N excretion, urinary N excretion was greater (P < 0.001) in H than in M and L diets, but no differences in faecal N excretion were observed among treatments. A third study with in vitro assays under aerobic and anaerobic conditions was designed to analyse gaseous emissions (volatilisation of N and carbon, C) during the storage stage of manure. Manure, faecal and urine samples, mixed at a ratio of 1:1 (wet weight), were collected during the N excretion study (manure-H, manure-M, manure-L). Under aerobic conditions, manure-M and manure-L showed a delay of 4–5 days in manure ammonia emission compared with manure-H (P < 0.01). Total N content was lower (P < 0.01) in manure-L compared with manure-M and manure-H, but N volatilisation (percentage relative to initial N) in manure-L and manure-M was greater (P < 0.01) than in manure-H. In contrast, the anaerobic N volatilisation was 20 times greater in manure-M and 10 times greater in manure-H compared with manure-L. Under aerobic and anaerobic conditions, the emission of C, as C-CO₂ and C-CH₄, was greater in manure-L than in manure-H and manure-M. Therefore, the decrease of dietary CP concentration from 17% to 14.5% and 12% is an efficient strategy to reduce urinary N excretion by 40%, without impairing performance, and also to reduce manure N losses through ammonia volatilisation under anaerobic conditions. However, a dietary CP content of 14.5% resulted in less environmental impact than a CP content of 12.8% when also considering manure emissions under aerobic or anaerobic conditions.     

Leaf-level nitrogen use efficiency: definition and importance

Nitrogen use efficiency (NUE) has been widely used to study the relationship between nitrogen uptake and dry mass production in the plant. As a subsystem of plant nitrogen use efficiency (NUE), I have defined leaf-level NUE as the surplus production (gross production minus leaf respiration) per unit amount of nitrogen allocated to the leaf, with factorization into leaf nitrogen productivity (NP) and mean residence time of leaf nitrogen (MRT). These concepts were applied to two herbaceous stands: a perennial Solidago altissima stand and an annual Amaranthus patulus stand. S. altissima had more than three times higher leaf NUE than A. patulus due to nearly three times longer MRT of leaf N. In both species, NUE and NP were higher at the leaf level than at the plant level, because most leaf N is involved directly in the photosynthetic activity and because leaf surplus production is higher than the plant net production. MRT was longer at the plant level. The more than twice as long MRT at the plant level as at the leaf level in S. altissima was due to a large contribution of nitrogen storage belowground in the winter in this species. Thus, comparisons between a perennial and an annual system and between plant- and leaf-level NUE with their components revealed the importance of N allocation, storage, recycling, and turnover of organs for leaf photosynthetic production and plant dry mass growth.     

不同缓控释肥对鲜食玉米产量、品质及氨挥发的影响

采用田间试验,设置不施氮对照(CK)、常规施肥(U)、增效尿素(DU)、包膜尿素(CU)、缓控释掺混尿素(CDU)共5个处理,研究了常规施肥(240 kg N·hm^-2)和不同缓控释肥料一次性减量施用(180 kg N·hm^-2)对鲜食玉米产量、品质与土壤无机氮变化和氨挥发的影响。结果表明: U处理氨挥发总量最高,追肥是产生氨挥发损失的重要因素;与U处理相比,DU、CU、CDU处理氨挥发减排78%～81%。收获后U处理80～100 cm土层硝态氮浓度最高,为51.6 mg·kg^-1,氮淋溶风险较高,而DU、CU、CDU处理同土层硝态氮含量均较低,降低了淋溶风险。与U处理相比,减氮25%的3个缓控释肥处理没有减产,并增加了籽粒维生素C、可溶性糖和蛋白质含量;缓控释肥处理之间,DU处理的氮肥农学效率和经济效益最高。综上,减量施用新型缓控释肥可以实现鲜食玉米稳产提质,显著降低氨挥发损失和硝态氮淋失风险。与成本较高的树脂包膜控释肥相比,双效抑制剂增效肥(DU)成本低、制作便捷,是鲜食玉米专用肥的较好选择。     

The simple open soil method of measuring urea volatilisation losses

Summary A simple technique of estimating ammonia volatilisation loss from urea applied to soil is described. The soil is incubated with urea, after which hydrochloric acid is added to prevent loss of N from the hydrolysed urea during drying of the soil. The volatilisation loss is estimated by difference between the N recovered from the soil and the urea applied. Recovery studies of urea hydrolysis on 3 Malaysian soils show that the hydrolysis products, consisting of ammonium N and any unreacted urea, can be quantitatively recovered from the soil by this technique, with average recoveries of 95%–97%. A cross-check by 9 laboratories indicated good accuracy and precision in the method. When the open soil method was compared with the direct measurement of ammonia loss in simple volatilisation chambers, it gave much higher results suggesting that the closed system of trapping tended to underestimate volatilisation losses during urea hydrolysis.     

覆膜与滴灌对河套灌区玉米花粒期叶片光合特征的影响

光合作用是作物生长发育和产量形成的基础,栽培方式和土壤含水量变化显著影响作物的光合作用.灌浆期和乳熟期是玉米花粒期2个重要阶段,是玉米籽粒形成和干物质积累的关键时期.通过大田试验研究了河套灌区不同覆膜方式与滴灌水平对不同生育时期玉米光合特征及产量的影响.结果表明: 灌浆期玉米叶片光合特征在不同处理下无显著差异,乳熟期净光合速率和蒸腾速率在半覆膜(B₂)和全覆膜(Q₂)滴灌水平2(350 mm)处理下均显著高于半覆膜(B₁)和全覆膜(Q₁)滴灌水平1(200 mm),并且B₁和Q₁处理下灌浆期叶片的净光合速率、蒸腾速率、水分利用效率及气孔导度等显著高于乳熟期.不同处理下灌浆期和乳熟期叶片的净光合速率、蒸腾速率,灌浆期的气孔导度以及乳熟期的水分利用效率等在日变化上存在着同步关系,均呈现出倒“U”型的日变化特征,而胞间CO₂浓度则呈现相反的变化趋势.逐步回归分析显示,光合有效辐射、大气温度和空气相对湿度等气象因子是影响玉米叶片光合特征的主要环境因子.此外,B₂和Q₂处理下玉米产量显著高于B₁和Q₁处理(分别增加了29.3%和50.9%),但B₁和Q₁处理间并无显著差异.这表明与覆膜方式相比,滴灌水平对干旱地区玉米产量的影响更大.     

定向种植对夏玉米群体内光环境及叶片光合性能的影响

为改善玉米群体内光环境,进一步提高玉米单株光合能力以获得高产,本研究以郑单958为试验材料,通过设置种子定向入土方式,研究了定向有序种植条件下群体内光分布特征,以及单株玉米穗位叶花后光合性能,并借助快速叶绿素荧光动力学曲线分析了与叶片光合性能有密切联系的光系统Ⅱ(PSⅡ)的性能特征.结果表明:叶片不同朝向显著改变夏玉米群体内穗位叶处光合有效辐射截获量,朝南处理(S)平均比朝北处理(N)高271.8%.不同朝向的叶片对高光与弱光的利用能力差异显著,朝南处理饱和光强下净光合速率(Pn)显著升高,表明其高光强利用能力显著提升;而朝北处理(N)表观量子效率(α)则随生育期推进显著增加,有利于叶片适应长期弱光环境.生育前期朝南处理PSⅡ电子供体侧和受体侧性能显著提高,进而改善了PSⅡ反应中心性能(PIABS)和荧光光化学淬灭系数(ψo),电子在电子传递链中转移效率(φEo)的提高增强了电子由PSⅡ向光系统Ⅰ(PSⅠ)的传递性能.生育前期叶片性能呈现出朝南>朝东>朝西>朝北的趋势.但成熟末期朝南处理对强光的利用效率显著降低,朝北处理在生育后期表现出较强的弱光利用能力,表观量子效率显著升高,花后40dPn与PSⅡ性能均表现为朝北>朝西>朝东>朝南的趋势.总体上,朝南与朝东处理群体内光环境改善显著,群体穗位层截获光合有效辐射较多,光合能力和干物质生产能力增强,有利于夏玉米产量提高.     

Fate of fertiliser N applied to wheat on a coarse textured highly calcareous soil under simulated semi-arid conditions

Background and Aims

Quantitative information on the fate and efficiency of nitrogen (N) fertiliser applied to coarse textured highly calcareous soils in semi-arid farming systems is scarce but, as systems intensify, is essential to support sustainable agronomic management decisions

Method

A glasshouse study was undertaken to trace the fate of N fertiliser applied to wheat (Triticum aestivum L. cv Yitpi) grown on a reconstructed profile (0 to 600 mm) of a grey highly calcareous (>35% CaCO₃) sandy loam soil. Two watering treatments were applied (drier and wetter) equivalent to low (decile 2, 179 mm) and medium (decile 5, 234 mm) growing season rainfall for a location with typical semi-arid environment in southern Australia. 15 N-labelled urea fertiliser (35.4 mg N/pot) was applied in a split application - at sowing and 70 days after sowing, followed by immediate watering or watering after delay of 1 week.

Results

Recovery of N fertiliser in grain (30 to 52%) was greater for the wetter treatment, and when water was applied immediately following fertiliser application. It was also similar for N applied at sowing and N applied during crop growth. Overall, more than 40% of the urea fertiliser N remained in the soil at anthesis, largely in the top 100 mm, indicating little movement of fertiliser N down the profile even with application of water. Losses of urea fertiliser N (13-24%) were considered relatively small given the highly calcareous nature of the soil; and were significantly greater from N applied during growth compared to at sowing, particularly where watering did not immediately follow application. There was no effect of fertiliser N on grain yield due to sufficient available N in soil at sowing (139mgN/pot), but N concentration and DM of stubbles was increased. Watering treatment did not affect shoot dry matter production up to anthesis, although root weight was higher in the wetter treatment, and grain yield was 9% greater.

Conclusions

It is concluded that the potential for N losses from urea applied to highly calcareous coarse textured soils in semi-arid agricultural areas appears relatively low. Further, where there are relatively large amounts of plant available N present at sowing, a strategy of delayed or withheld applications of N to manage economic risk may have minimal effects on grain production in seasons with drier than average rainfall.     

Regulation of Nitrogen Metabolism,Photosynthetic Activity,and Yield Attributes of Spring Wheat by Nitrogen Fertilizer in the Semi-arid Loess Plateau Region

It is critical for spring wheat (Triticum aestivum L.) production in the semi-arid Loess Plateau to understand the impact of nitrogen (N) fertilizer on changes in N metabolism, photosynthetic parameters, and their relationship with grain yield and quality. The photosynthetic capacity of flag leaves, dry matter accumulation, and N metabolite enzyme activities from anthesis to maturity were studied on a long-term fertilization trial under different N rates [0 kg ha^?1(N1), 52.5 kg ha^?1 (N2), 105 kg ha^?1 (N3), 157.5 kg ha^?1 (N4), and 210 kg ha^?1 (N5)]. It was observed that N3 produced optimum total dry matter (5407 kg ha^?1), 1000 grain weight (39.7 g), grain yield (2.64 t ha^?1), and protein content (13.97%). Our results showed that N fertilization significantly increased photosynthetic parameters and N metabolite enzymes at all growth stages. Nitrogen harvest index, partial productivity factor, agronomic recovery efficiency, and nitrogen agronomic efficiency were decreased with increased N. Higher N rates (N3–N5) maintained higher photosynthetic capacity and dry matter accumulation and lower intercellular CO₂ content. The N supply influenced NUE by improving photosynthetic properties. The N3 produced highest chlorophyll content, photosynthetic rate, stomatal conductance and transpiration rate, grain yield, grain protein, dry matter, grains weight, and N metabolite enzyme activities compared to the other rates (N1, N2, N4, and N5). Therefore, increasing N rates beyond the optimum quantity only promotes vegetative development and results in lower yields.

     

两种配比的控释肥对杭白菊养分吸收和生长效应的影响

利用盆栽试验研究两种不同配比的控释复合肥CRFA（4%树脂包膜,N∶P₂O₅∶K₂O为14∶14∶14）和CRFB（4%树脂包膜,N∶P₂O₅∶K₂O为20∶8∶10）及普通复合肥CCF（N∶P₂O₅∶K₂O为15∶15∶15）对杭白菊营养吸收和生长效应的影响.结果表明：普通复合肥CCF1（每盆6 g氮素用量的CCF）和CCF2（每盆3 g氮素用量的CCF）施入土壤后30 d,土壤中碱解氮、有效磷、有效钾含量分别为163.29和145.26 mg·kg^-1、180.39和163.13 mg·kg^-1、300.08 和213.15 mg·kg^-1,而后迅速下降.控释复合肥养分释放较慢,其土壤碱解氮含量在施肥后缓慢升高,在施肥后60 d达到高峰,此时CRFA1（每盆6 g氮素用量的CRFA）、CRFB1（每盆6 g氮素用量的CRFB）、CRFA2（每盆3 g氮素用量的CRFA）、CRFB2（每盆3 g氮素用量的CRFB）分别为129.51、138.65、118.36、126.31 mg·kg^-1;CRFA1和CRFA2处理土壤有效磷含量与CCF处理变化趋势基本一致,施肥后30 d分别达到169.54和133.46 mg·kg^-1,CRFB1和CRFB2处理在施肥后60 d左右达到释放高峰,含量分别为137.13和84.68 mg·kg^-1,然后缓慢下降.两种不同养分配比的控释复合肥处理植株叶面积、叶面积系数、分枝数、开花率、每株花数、鲜花直径等农艺性状均明显优于等氮素用量的普通复合肥处理,其中CRFB控释效果优于CRFA,其更符合杭白菊对养分的需求,且在本试验条件下,CRFB2处理产量最高.     

黄土高原南部春玉米地膜栽培的水肥效应与氮肥去向

在黄土高原南部采用田间小区和微区试验,研究了春玉米地膜栽培下氮肥-水分-产量关系与氮肥去向。结果表明,相同施肥条件下地膜栽培(N120C)比平作栽培(N120UC)增产显著(46．7％),施用氮肥显著地发挥了地膜的增产潜力,处理N120(尿素氮120kg·hm^-2)、N180(尿素氮180kg·hm^-2)和N120M(尿素氮120kg·hm^-2+有机肥氮60kg·hm^-2),籽粒产量比对照CK(不施氮)分别增产41．8％、43．9％和34．7％,地膜栽培或施用氮肥都极大地改善了玉米水分生产效率(WUE)和降水利用率(RUE),试验中N120C比N120UC水分生产效率提高57．9％。降水利用效率提高54．5％;处理N120、N180和N120M比CK处理WUE分别提高38．4％、47．4％和32．4％,RUE分别提高42．3％、43．9％和34．7％,由于供试有机肥是半腐解的牛粪,比尿素氮素供给迟缓,所以对玉米产量和WUE提高幅度小,试验水分测定反映出,玉米利用的水分73．0％～83．7％来自降雨,表明决定春玉米产量的关键水分是生育期降水,玉米地膜栽培对氮肥去向有微弱影响,相对于平作玉米,氮肥总的回收率差异不大,但氮肥利用率下降7．3个百分点,土壤残留率上升6．4个百分点,土壤当季残留氮主要集中在0～20cm,不会发生向深层大量的淋溶和累积。     

Does leaf shedding increase the whole-plant carbon gain despite some nitrogen being lost with shedding?

When old leaves are shed, part of the nitrogen in the leaf is retranslocated to new leaves. This retranslocation will increase the whole-plant carbon gain when daily C gain : leaf N ratio (daily photosynthetic N-use efficiency, NUE) in the old leaf, expressed as a fraction of NUE in the new leaf, becomes lower than the fraction of leaf N that is resorbed before shedding (R(N)). We examined whether plants shed their leaves to increase the whole-plant C gain in accord with this criterion in a dense stand of an annual herb, Xanthium canadense, grown under high (HN) and low (LN) nitrogen availability. The NUE of a leaf at shedding expressed as a fraction of NUE in a new leaf was nearly equal to the R(N) in the LN stand, but significantly lower than the R(N) in the HN stand. Thus shedding of old leaves occurred as expected in the LN stand, whereas in the HN stand, shedding occurred later than expected. Sensitivity analyses showed that the decline in NUE of a leaf resulted primarily from a reduction in irradiance in the HN stand. On the other hand, it resulted from a reduction in irradiance and also in light-saturated photosynthesis : leaf N content ratio (potential photosynthetic NUE) in the LN stand.     

Nitrogen balance of effluent irrigated silage cropping systems in southern Australia

The nitrogen (N) balance in a double-cropped, effluent spray irrigation system was examined for several years in southern Australia. The amounts of N added by irrigation, removed in the crop, and lost by ammonia (NH3) volatilisation, denitrification, and leaching were measured. Results from the project provide pig producers with the knowledge necessary to evaluate the efficiency of such systems for managing N, and enable sustainable effluent reuse practices to be developed. Oats were grown through the winter (May to November) without irrigation, and irrigated maize was grown during the summer/autumn (December to April). Approximately 18 mm of effluent was applied every 3 days. The effluent was alkaline (pH 8.3) and the average ammoniacal-N (NH4+ + NH3) concentration was 430 mg N/l (range: 320 to 679 mg N/l). Mineral N in the 0- to 1.7-m layer tended to increase during the irrigation season and decrease during the winter/spring. About 2000 kg N/ha was found in the profile to a depth of 2 m in October 2000. N removed in the aboveground biomass (oats + maize) was 590 and 570 kg N/ha/year, equivalent to 25% of the applied N. Average NH3 volatilisation during the daytime (6:00 to 19:00) was 2.74 kg N/ha, while volatilisation at night (19:00 to 6:00) was 0.4 kg N/ha, giving a total of 3.1 kg N/ha/day. This represents approximately 12% of the N loading, assuming that these rates apply throughout the season. The balance of the N accumulated in the soil profile during the irrigation season, as 15N-labelled N studies confirmed. The high recovery of the 15N-labelled N, and the comparable distribution of 15N and Br in the soil profile, implied that there was little loss of N by denitrification, even though the soil was wet enough for leaching of both tracers.     

有机物沟埋还田模式与花后灌水量对玉米光合特性和产量的影响

有机物沟埋还田与花后灌水配合对增加玉米田保水供水能力,提高玉米花后光合性能、实现节水增产有重要意义.本试验以郑单958为供试材料,设置有机物沟埋还田和花后灌水量两个因素,有机物沟埋还田包括不还田(M₀)、秸秆单还田(M₁)和牛粪秸秆混合还田(M₂)3个还田类型,花后灌水量包括450 mm(W₁)和325 mm(W₂)2个水平,研究了其对玉米穗位叶光合性能、光系统Ⅱ(PSⅡ)效率和产量等的影响.结果表明:与秸秆单还田比较,牛粪秸秆混合还田有效提高了玉米花后光合能力和各器官的干物质积累量;与节水灌溉相比,正常灌溉加强了有机物还田对玉米光合能力的促进作用.牛粪秸秆混合还田与正常灌溉结合可显著提高玉米花后叶片的光合速率(P_n)、气孔导度(g_s)和蒸腾速率(T_r),降低胞间CO₂浓度(C_i);提高玉米花后叶片PSⅡ的最大光化学效率(φ_po)和捕获的激子将电子传递到电子传递链中Q_A下游的电子受体的概率(Ψ_o);改善花后叶片光能利用率,维持花后叶片较高的光合性能;同时增加花后玉米各器官干物质的量,提高干物质总积累量和转运能力,有利于花后同化物对籽粒的分配,最终获得高产.节水灌溉降低了叶片的光合性能,造成产量的下降;但配合牛粪秸秆混合还田与不还田处理相比,水分利用效率、籽粒增长速率和增产效果均优于正常灌水.这表明牛粪秸秆混合还田与正常灌溉结合可有效提高玉米花后光合性能,增加干物质积累量,促进玉米增产;牛粪秸秆混合还田与节水灌溉结合一定程度上降低了因减少灌溉量造成的减产.     

Effects of nitrogen deficiency on photosynthetic traits of maize hybrids released in different years

BACKGROUND AND AIMS: New maize (Zea mays) hybrids outperformed old ones even at reduced N rates. Understanding the mechanisms of the differences in performance between newer and older hybrids under N deficiency could provide avenues for breeding maize cultivars with large yield under N deficiency, and reduce environmental pollution caused by N fertilizers. METHODS: N deficiency effects on grain weight, plant weight, harvest index, leaf area and photosynthetic traits were studied in the field for six maize hybrids released during the past 50 years to compare their tolerance and to explore their physiological mechanisms. KEY RESULTS: N deficiency decreased grain yield and plant weight in all hybrids, especially in the older hybrids. However, there was no significant difference in harvest index, rate of light-saturated photosynthesis (Psat) 20 d before flowering, leaf area or plant weight at flowering between the N-deficient and control plants of all hybrids. Dry matter production after flowering of the N-deficient plants was significantly lower than that of the control plants in all hybrids, especially in the older hybrids, and was mostly due to differences in the rate of decrease in photosynthetic capacity during this stage. The lower Psat of the older hybrids was not due to stomatal limitation, as there was no significant difference in stomatal conductance (gs) and intercellular CO2 concentration (Ci) between the hybrids. N deficiency accelerated senescence, i.e. decreased chlorophyll and soluble protein contents, after anthesis more for the earlier released hybrids than for the later ones. N deficiency decreased phosphoenolpyruvate carboxylase (PEPCase) activity significantly more in older hybrids than newer hybrids, and affected the maximal efficiency of PSII photochemistry (Fv/Fm) only in the old hybrids and at the late stage. CONCLUSIONS: Compared with older (earlier released) hybrids, newer (later released) hybrids maintained greater plant and grain weight under N deficiency because their photosynthetic capacity decreased more slowly after anthesis, associated with smaller non-stomatal limitations due to maintenance of PEPCase activity, and chlorophyll and soluble protein content.     

Production of 15N-Labelled Liquid Organic Fertilisers Based on Manure and Crop Residue for Use in Fertigation Studies

Large quantities of crop residue and animal manure from agricultural and livestock activities are annually produced worldwide. With proper management, these residues are potentially valuable sources of plant nutrients, mainly N. Recycling such subproducts in sustainably-based agricultural systems can minimise the use of mineral fertilisers, and hence reduce the potential risk of surface and groundwater pollution. Therefore, the purpose of this study was to obtain (small scale) two liquid labelled-organic fertilisers, an animal- and a vegetal-based organic (AO and VO, respectively) fertiliser, to be used as organic N sources in subsequent fertigation studies. Forage maize (Zea mays L.) grown under ¹⁵N-labelled fertiliser supply was used as raw material for VO fertiliser production, and also as ¹⁵N-labelled sheep feed to obtain ¹⁵N-labelled manure. The labelled faeces fraction was used as raw material for the AO fertiliser. The VO fertiliser was obtained after an acidic and an enzyme-driven hydrolysis. The AO fertiliser was obtained after acidic hydrolysis. The VO liquid fertiliser presented an N concentration of 330 mg·L^-1, 85% of total N was organic, while ammonium and nitrate N accounted for 55% and 45% of the mineral nitrogen fraction, respectively. This fertiliser also exhibited high K, Ca and S concentrations and notable values for the remaining macro- and micronutrients. The AO liquid fertiliser had a similar total N concentration (496 mg·L^-1, 82% of total N in an organic form) to that of VO, but its mineral N fraction significantly differed, which came in a predominantly (95%) ammonia form. It also had a high content of N, P, K and other macronutrients, and sufficient Fe, Zn, Mn, Cu and B levels, which suggests its suitability as a potential fertiliser. The percentage of ¹⁵N enrichment in both VO and AO liquid fertilisers exceeded 2% ¹⁵N atom excess, which enabled their use in subsequent assays run to assess nitrogen uptake efficiency.