添加生化抑制剂和腐植酸的稳定性增效尿素在黄土中的施用效果

采用田间盆栽试验,研究生化抑制剂与生物刺激素腐植酸结合制成的高效稳定性增效尿素肥料在黄土中的氮素转化特征、增产效果和氮素肥料表观利用率,以探明其施用效果,为开发适宜黄土施用的新型增效尿素肥料提供理论依据。本研究以不施氮肥(CK)和施尿素氮肥(N)为对照,在尿素中分别添加腐植酸(F)、N-丁基硫代磷酰三胺(NBPT)、3,4-二甲基吡唑磷酸盐(DMPP)和2-氯-6-三甲基吡啶(CP),以及腐植酸与3种生化抑制剂分别组合(NBPT+F、DMPP+F、CP+F)。结果表明: 与N处理相比,F、NBPT+F、DMPP+F和CP+F处理均能显著提高玉米的产量、叶片叶绿素含量、叶面积指数和植株吸氮量,对土壤铵态氮和硝态氮含量也有显著影响。与单独施用生化抑制剂相比,添加腐植酸可提高玉米叶片叶绿素含量。与CP相比,CP+F玉米的植株吸氮量、叶绿素含量、氮肥吸收利用率均显著提高;与NBPT相比,NBPT+F硝化抑制率提高10.7%,但玉米产量、叶面积指数、植株吸氮量和氮肥利用率等均有所降低;与DMPP相比,DMPP+F显著降低了玉米产量、叶面积指数、植株吸氮量、氮肥利用率和硝化抑制率等。综合玉米产量、植株吸氮量、氮肥吸收利用率以及土壤铵态氮、硝态氮含量等指标,在黄土地区施用尿素肥料时,建议添加腐植酸和CP以提升尿素性能,从而提高产量和肥料利用率。     

不同土层深度配施缓释/普通尿素对土壤氮素和酶活性及玉米产量的影响

通过2017—2018两年田间试验,研究了不同土层深度配施缓释(PCU)/普通尿素(PU)对0～30 cm土层土壤无机氮含量、酶活性和玉米产量的影响。试验设置不施氮肥(CK)、普通尿素一次施肥(PU₁,5～10 cm土层)、普通尿素传统两次施肥(PU₂,5～10 cm土层,60%种肥+40%追肥)、普通尿素一次分层施肥(PU₃,5～10 cm土层20%N+15～20 cm土层30%N+25～30 cm土层50%N)、不同土层深度缓释/普通尿素配施[PCU₁～PCU₄,均为5～10 cm土层20%N(普通尿素)+15～20 cm土层30%N(配施)+25～30 cm土层50%N(配施),其中PCU₁～PCU₄的15～20和25～30 cm土层PCU:PU分别为3:7、3:7,5:5、5:5, 3:7、5:5, 5:5、3:7]共8个处理。结果表明: 与CK相比,PU₁能够满足玉米生育前期对0～10 cm土层氮素的需求,PU₂和PU₃能够满足玉米发育前期对10～30 cm土层氮素的需求,不同土层深度配施缓释/普通尿素能够满足玉米整个生育时期对氮素的需求。与PU₁～PU₃相比,不同土层深度配施缓释/普通尿素可显著增加灌浆期和成熟期10～20和20～30 cm土层NO₃^--N、NH₄⁺-N、碱解氮含量和脲酶、蛋白酶活性。与PU₃相比,不同土层深度配施缓释/普通尿素处理2017和2018年玉米产量分别提高2.3%～24.6%和1.3%～16.5%,PCU₄产量最高,分别达13899和12439 kg·hm^-2。因此,不同土层深度配施缓释/普通尿素既能满足玉米生育前期对氮素的需求,也能提高生育后期10～30 cm土层土壤无机氮含量和酶活性,促进玉米生长,增加玉米产量,其中PCU₄处理施肥方式最佳。     

Use of tropical maize for bioethanol production

Tropical maize is an alternative energy crop being considered as a feedstock for bioethanol production in the North Central and Midwest United States. Tropical maize is advantageous because it produces large amounts of soluble sugars in its stalks, creates a large amount of biomass, and requires lower inputs (e.g. nitrogen) than grain corn. Soluble sugars, including sucrose, glucose and fructose were extracted by pressing the stalks at dough stage (R4). The initial extracted syrup fermented faster than the control culture grown on a yeast extract/phosphate/sucrose medium. The syrup was subsequently concentrated 1.25–2.25 times, supplemented with urea, and fermented using Saccharomyces cerevisiae for up to 96 h. The final ethanol concentrations obtained were 8.1 % (v/v) to 15.6 % (v/v), equivalent to 90.3–92.2 % of the theoretical yields. However, fermentation productivity decreased with sugar concentration, suggesting that the yeast might be osmotically stressed at the increased sugar concentrations. These results provide in-depth information for utilizing tropical maize syrup for bioethanol production that will help in tropical maize breeding and development for use as another feedstock for the biofuel industry.     

Effect of wilting and the additives,straw, molasses and urea on the fermentation pattern of maize silage

The process of ensiling was studied in fresh maize (15% dry matter (DM)), wilted maize (18 and 24% DM) and maize mixed with 5–20% of wheat straw (18, 25 and 29% DM). Silages with 24% DM were preserved better than those with lower dry matter content. There was a significant change, with time, in pH, titrable acidity, volatile fatty acids, lactic acid, number of lactic acid bacteria, volatile nitrogen and soluble sugars in all the treatments. There was a significant decline in volatile fatty acids (P<0.05) and ammonia (P<0.01) production, and a significant increase in soluble sugar (P<0.01) in silages made after wilting. A significant decline in titrable acidity (P<0.01), volatile fatty acid production (p<0.05) and ammonia nitrogen (P<0.01), and a significant increase in pH (P<0.01) were found in silages of maize mixed with wheat straw. The overall rate of fermentation decreased during the first few days of fermentation in wilted and wheat straw silages, but the final products had characteristics of a good silage. In the second experiment the effect of urea and molasses was studied on wheat straw plus maize (15:85) silage with an initial DM content of 31–34%. Three levels of molasses (0, 3 and 6% of fresh weight) and two levels of urea (0 and 0.5% of fresh weight) were studied. Urea treatment with 3% molasses was found to be the best on the basis of silage characteristics.     

Nitrogen use efficiency of monoculture and hedgerow intercropping in the humid tropics

The design of productive and efficient intercropping systems depends on achieving complementarity between component species resource capture niches. Spatiotemporal patterns of capture and use of pruning and urea nitrogen (N) by trees and intercrops were elucidated by isotopic tracing, and consequences for nitrogen use efficiency were examined. During the first cropping season after applying urea–¹⁵N, maize accounted for most of the plant ¹⁵N recovery in Peltophorum dasyrrachis (33.5%) and Gliricidia sepium (22.3%) hedgerow intercropping systems. Maize yield was greatest in monoculture, and maize in monoculture also recovered a greater proportion of urea ¹⁵N (42%) than intercropped maize. Nitrogen recovery during active crop growth will not be increased by hedgerow intercropping if hedgerows adversely affect crop growth through competition for other resources. However, hedgerows recovered substantial amounts of ¹⁵N during both cropping cycles (e.g. a total of 13–22%), showing evidence of spatio-temporal complementarity with crops in the spatial distribution of roots and the temporal distribution of Nuptake. The degree of complementarity was species-specific, showing the importance of selecting appropriate trees for simultaneous agroforestry. After the first cropping season 17–34% of ¹⁵N applied was unaccounted for in the plant-soil system. Urea and prunings N were recovered by hedgerows in similar amounts. By the end of the second (groundnut) cropping cycle, total plant ¹⁵N recovery was similar in all cropping systems. Less N was taken up by the maize crop from applications of labelled prunings (5–7%) than from labelled urea (22–34%), but the second crop recovered similar amounts from these two sources, implying that prunings N is more persistent than urea N. More ¹⁵N was recovered by the downslope hedgerow than the upslope hedgerow, demonstrating the interception of laterally flowing N by hedgerows.     

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。     

深松与包膜尿素对玉米田土壤氮素转化及利用的影响

耕作方式和氮肥施用是影响土壤中氮肥转化、利用效率和作物产量的重要因素。通过夏玉米田的2a(2011—2012)定位试验,研究了两种耕作方式(深松、旋耕)配合不同尿素类型(包膜尿素、普通尿素)的施用对玉米田土壤硝态氮和铵态氮含量、脲酶活性、硝化细菌和反硝化细菌数量、玉米产量以及氮肥农学效率的影响。研究结果表明:相同耕作方式下,包膜尿素处理土壤中脲酶活性较稳定,且增加了旱田土壤亚硝酸细菌数量而降低了反硝化细菌数量,有利于土壤硝态氮含量的提高,尤其是作物生长的中后期;包膜尿素处理的产量比普通尿素提高7.25%—10.82%,同时提高氮肥农学效率。深松处理增加了土壤中的反硝化细菌数量,配合施用包膜尿素进一步提高了土壤脲酶活性,增加了亚硝酸细菌数量;旋耕与包膜尿素配合施用在一段时期内能显著增加土壤硝态氮含量,减少反硝化细菌数量。深松配合包膜尿素处理能够显著的增加玉米产量,2a分别比旋耕配合包膜尿素增加1.41%和10.62%。因此,深松措施配合施用包膜尿素能够增强土壤脲酶活性,增加亚硝酸细菌数量,提高氮素转化速率,增加作物产量和氮肥农学效率,其稳产效果在干旱年份尤为显著。     

控释尿素和普通尿素配比对不同氮效率玉米叶片衰老特性和土壤酶活性的影响

控释尿素和普通尿素配比施用可以同步玉米氮素需求,延缓后期衰老,增加产量。本试验以黄淮海区域两种氮效率玉米作为对象,研究控释尿素和普通尿素不同配比对其叶片衰老特性、土壤酶活性和土壤无机氮的影响。试验选取黄淮海主栽玉米品种豫禾988（氮低效）和郑单958（氮高效）作为试验材料,设置6个施氮处理（CK、N180U、N180C1、N180C2、N180C、N300U）,其中CK为不施氮处理,180、300代表施氮水平分别为180 kg/hm²和300 kg/hm²,U代表全尿素处理（基肥：追肥=2：3）,C1、C2分别代表控释氮：尿素氮为1：2和2：1（基肥一次施用）,C代表全控释尿素处理（基肥一次施用）。2018-2019年结果表明：与CK相比,豫禾988在N180C1和郑单958在N180C2处理下,能够在玉米生育后期显著提高穗位叶超氧化物歧化酶（SOD）和过氧化物酶（POD）活性,降低膜脂过氧化物（MDA）含量,同时也增加了土壤无机氮含量、脲酶和蔗糖酶活性。综上所述,针对不同氮效率玉米品种,通过控释尿素和尿素合理配施,利用速效氮和控释氮的释放来延缓玉米功能叶片衰老,延长功能期,提高生育后期土壤无机氮含量和酶活性,共同促进玉米生长,增加玉米产量,其中豫禾988和郑单958分别在N180C1和N180C2处理下效果最佳。     

不同施氮措施对旱作玉米地土壤酶活性及CO2排放量的影响

对施用速效氮肥(尿素)和缓释氮肥的旱作夏玉米地土壤酶活性及CO2排放量进行分析。结果表明,与不施肥处理比较,不同氮肥种类和施用量均可显著提高土壤脲酶、蔗糖酶、过氧化氢酶活性和CO2的排放量。在整个生育期,尿素与缓释氮肥处理土壤酶活性和土壤CO2排放量表现出相同变化趋势,尿素和缓释氮肥处理土壤CO2平均排放量分别为459.12 mg·m-·2h-1和427.11 mg·m-·2h-1,两者达到显著差异水平(P<0.5)。相关分析表明,土壤脲酶、蔗糖酶和过氧化氢酶活性与土壤CO2排放量呈显著或极显著正相关,相关系数分别为0.79、0.64和0.80。说明相同施氮量缓释氮肥较尿素能有效提高土壤酶活性并降低土壤碳排放量。     

Rotation of maize with cowpea improves yield and nutrient use of maize compared to maize monocropping in an alfisol in the northern Guinea Savanna of Ghana

In the northern Guinea Savanna of Ghana (1984–1987) a field experiment was conducted to study the reasons for beneficial effects of rotating maize (Zea mays) and cowpea (Vigna unguiculata) on yield and N and P use of maize. The treatments included two cropping systems, maize monocropping and maize/cowpea rotation, two levels of nitrogen (0 and 80 kg N ha^-1 as urea) and two levels of phosphorus application (0 and 60 kg ha^-1 P as Volta phosphate rock). Yields and nutrient accumulation of maize were larger in rotation than in monocropping, independent of the N and P level. Fertilizer application (N and P) increased yields of maize in both cropping systems to the same extent. Nitrate contents of the soil after cowpea and after maize monoculture were comparable at the beginning of the cropping period. Also, potential nitrogen mineralization was only slightly larger after cowpea in the unfertilized plots. However, soil nitrate of fertilized plots was similar or even higher under monocropping than under crop rotation, especially in deeper soil layers and at the end of the cropping period. This indicates that in addition to the availability of mineral N, its use by the plants was limiting for the productivity of maize. Root length densities of maize were significant lower in monocropped maize than in maize grown in rotation. Soil physical parameters (infiltration, bulk density, aggregate stability and water capacity) showed a significant deterioration compared to a bush fallow plot, but differed only slightly between the cropping systems. Also in a pot experiment maize growth was much better in the soil from the crop rotation than from the monocropping plots, provided P was eliminated as the main growth-limiting factor. Since this effect persisted in spite of N application and optimization of soil physical properties by mixing the soil with polystyrol it is concluded that the results indicate that yield decline in maize monocropping might be due to allelopathic effects.     

Effect of rates of nitrogen and relative efficiency of sulphur-coated urea and nitrapyrin-treated urea in dry matter production and nitrogen uptake by rice

Summary A field experiment conducted for two rainy seasons (1974 and 1975) on a sandy clay loam soil at the Indian Agricultural Research Institute, New Delhi showed that at 100kg N/ha the apparent recovery of urea nitrogen by the rice crop was only 28%, which was raised to 41.7% by treating urea with Nitrapyrin and to 47.4% by coating urea withneem (Azadirachta indica Juss) cake. The recovery with sulphur-coated urea was 37.7%. Dry matter production nitrogen concentration in plant and uptake by rice were increased as the rate of nitrogen was increased from 0 to 150kg N/ha. Advantage of treating urea with Nitrapyrin or coating withneem cake was seen more in grain than straw yield.     

The fate of nitrogen under maize and pasture cultivated on an alfisol in the western Llanos savannas,Venezuela

A field experiment was designed to follow the fate of fertilizer nitrogen in an annual crop (maize) and a permanent meadow (Digitaria decumbens) cultivated on an alfisol under the tropical two-season-climate of the Venezuelan Llanos.¹⁵N labelled urea equivalent to 150 kg N.ha^–1 was added to field plots and to lysimeters of undisturbed soil.Results obtained after the first year show that the accumulation of fertilizer nitrogen was twice as great in the aboveground parts of maize and accompanying weeds (29% of the added nitrogen) than in the aerial parts of grass (16%), while the reverse trend was shown by roots: about 2% of the added nitrogen was detected in corn roots and more than 4% in the underground biomass of the meadow. Leaching losses were less than 2% under maize and almost nil under pasture in spite of intensive leaching which occured during the rainy season.The top-soil (0–40 cm) of the grassland retained about 50% of the fertilizer nitrogen while only about 25% remained in the top-soil of the maize plot. The loss of fertilizer could be explained, largely, either by volatilisation immediately after application, or denitrification during the following weeks. The relative proportions of fertilizer-N and soil-N in maize and grass suggest that, during this period, gross mineralization of soil-N in both agroecosystems attained a value almost equivalent to the total nitrogen added in the fertilizer. The implications of these results when converting natural savannas into cultivated regimes are very different in the case of permanent pasture, which can improve the organic status of these poor soils and annual crops, like maize, which induce an unavoidable deficit in the nitrogen balance.     

N-lignin and margosa (neem) seed cake-blended urea as nitrogen source for wheat

Summary In a field experiment on wheat, N-lignin was found as effective as urea in increasing grain yield and nitrogen uptake by the crop. N-lignin also left higher amount of fertilizer residue in the hydrolysable organic-N fraction in the soil than did urea. The effect of margosa (neem) seed cake blended urea on the grain yield, N uptake and soil N was similar to ordinary urea. Supplementing N-lignin with urea did not show any advantage.Phosphorus uptake by wheat crop was enhanced and potassium uptake was depressed by application of N-lignin. Neem seed cake also stimulated phosphorus uptake slightly but had no effect on potassium uptake.     

Effect of urea and amino acids of the ornithine cycle on the biomass accumulation and amino acids synthesis by Candida guilliermondii]

When assimilating urea, arginine, ornithine and citrulline as the sole source of nitrogen, C. guilliermondii shows a higher economic coefficient of biomass accumulation (54.2, 59.7, 40.6% respectively) as compared with ammonium sulphate whose coefficient is 35.6%. Nitrogen sources exert a significant influence on the content of essential amino acids in the alcohol soluble fraction of cell biomass. For instance, urea and arginine are responsible for the accumulation of ornithine (220 and 480 mug/100 mg abs. dry weight), arginine (470 and 587 mug), aspartic acid (220 mug), glutamic acid (520 and 444 mug), alanine (460 and 500 mug), whereas ammonium sulphate provides an accumulation of serine--52 mug, glycine--57 mug, gamma-aminobutyric acid--480 mug, phenyl alanine--96 mug and leucine--96 mug.     

Response of rice to different forms of urea and phosphorus fertilization under intermediate deepwater conditions (15–50 cm)

Summary Under intermediate deepwater condition with water depths of 15–35 cm during most of the crop growth period, sulphur coated urea and urea supergranule placement was superior to prilled urea in increasing the relative uptake and grain yield (23–25%) of rice. A semi-tall variety (CR 1016) responded better to the nitrogen application than a tall variety (CR 1030).The crop fertilized with N produced more number of tillers and grain yield than the unfertilized crop under complete submergence for 6 days at seedling establishement stage (8 days after transplanting) followed by waterlogging of 25±5 cm throughout the crop growth period. Application of phosphorus together with nitrogen increased the grain yield (9–14%) over nitrogen alone. Crop fertilized with these two nutrients (NP) increased their uptake and yield components.     

Organic acids in the rhizosphere of Zea mays and Phaseolus aureus plants

Summary Soils from rhizosphere and non-rhizosphere of maize and mung crops and an uncultivated field were analysed for organic carbon, total nitrogen, cation exchange capacity and pH. The rhizosphere soils showed higher carbon and nitrogen content than non-rhizosphere soils. Phenolic acids viz, vanillic, p-hydroxybenzoic, p-coumaric, salicylic and syringic and pyrocatechol were detected in different cultivated and uncultivated soils. Pyrocatechol was absent from rhizosphere soils of both crops while p-coumaric and salicylic acids were not detected in rhizosphere of mung crop and nonrhizosphere of maize crop respectively. Syringic acid was present only in case of maize. Gluconic, tartaric, and citric acids were also detected in different soils. re]19720712     

A comparison of the isotope recovery and difference methods for determining nitrogen fertilizer efficiency

In an experiment with sorghum on a medium deep red soil (Udic Rhodustalf) at Patancheru, India, where¹⁵N-labeled urea was applied at different rates during the 1981 rainy season, the apparent (ARF) and isotope recovery fractions (¹⁵NRF) were appreciably different, particularly at lower rates of fertilizer application. The fertilizer rates were corrected for losses of fertilizer nitrogen, that were estimated from the differences in the amounts of¹⁵N recovered in the soil and the crop, and the known amounts of¹⁵N applied. Introducing these ‘effective’ fertilizer rates, the apparent discrepancy between ARF and¹⁵NRF could be explained if it were assumed that the¹⁵N immobilized in the organic soil fraction was not remineralized during the course of the growing season. In the difference method, the equivalent amount of nitrogen at natural abundance released in exchange for fertilizer nitrogen (5 atom % xs¹⁵N) immobilized in the organic nitrogen fraction is treated as ‘fertilizer nitrogen’, since no distinction is made between¹⁴N and¹⁵N. In the isotope-dilution method, the nitrogen at natural abundance mineralized during biological interchange is not considered fertilizer nitrogen, and therefore the assumed effective amount of fertilizer nitrogen available to the crop is less than in the difference method.     

减氮配施有机物料对玉米-白菜轮作系统作物产量、光合特性和产品品质的影响

减氮配施有机物料是实现农作物减肥不减产甚至增产的重要措施之一。为了探究减氮配施有机物料对贵州黄壤区玉米-白菜轮作系统作物产量、光合特性和农产品品质的影响,本研究采用盆栽试验,以玉米和白菜作为供试作物,研究了不施肥(CK)、常规化肥(CF)、减氮(20%)配施生物炭(RF+B)、减氮配施菜籽饼(RF+O)、减氮配施生物炭和菜籽饼(RF+BO)处理,对玉米苗期、拔节期、抽穗期、成熟期和白菜苗期、生长期、收获期植株叶片光合特性、生物性状、产量和品质的影响。结果表明: 与CF处理相比,RF+BO处理显著增加了玉米和白菜产量,增幅分别为9.7%和39.2%,RF+O处理对玉米和白菜产量的影响不显著,RF+B处理玉米增产不明显。RF+BO处理改善了玉米和白菜的生物性状,显著提升了玉米百粒重和白菜的株高、最大叶长、总生物量;延长了玉米和白菜持绿期及高光合持续时间,其中,玉米苗期、拔节期、抽穗期和成熟期叶片SPAD值分别增加42.7%、11.0%、12.8%和30.2%,白菜苗期、生长期和收获期叶片SPAD值分别增加13.5%、9.2%和12.5%;玉米苗期、抽穗期和成熟期的净光合速率(P_n)分别增加11.1%、10.9%和119.8%,白菜生长期和收获期的P_n分别提高12.7%和14.6%;玉米抽穗期和收获期的气孔导度(g_s)分别增加58.3%和41.7%,白菜苗期、生长期和收获期的g_s分别增加10%、64.7%和19.2%;玉米苗期、拔节期、抽穗期和成熟期的蒸腾速率(T_r)分别增加55.0%、10.6%、14.0%和143.9%,白菜生长期的T_r增加26.1%。同时,玉米和白菜的营养品质明显改善,玉米籽粒还原糖、淀粉和粗蛋白含量分别提高16.2%、3.5%和20.3%,白菜Vc、氨基酸和还原糖含量分别提高26.3%、21.0%和27.8%。这说明本试验条件下,减氮20%配施生物炭和菜籽饼组合对贵州黄壤玉米-白菜轮作系统的作物生长、产量提升、持绿期和高光合持续时间的延长、农产品品质改良均有积极效应,总体上在所有处理中提升效果最佳。减氮下单一配施有机物料对作物产量、光合和品质的整体影响不明显。     

冬小麦／夏玉米轮作体系中土壤氮素矿化及预测

应用田间试验结果研究了冬小麦和夏玉米生长期的土壤氮素矿化量,并用间隙淋洗好气培养试验结合一级动力学模型对田间氮素矿化量进行了预测。结果表明,土壤氮素矿化量在年际间和作物间的变异很大,夏玉米季一般高于冬小麦季,从而导致夏玉米季施用氮肥的增产作用不明显,冬小麦季矿化量占当季作物最高吸氮量的31％～60％,夏玉米季占62％～108％,加上起始Nmin的供氮,造成了作物产量尤其是夏玉米产量对施入氮肥反应不明显,土壤氮素净矿化量均随土壤供氮量的增加而显著减少,在一般供氮量范围内(0～300kgN·hm^-2)均表现为净矿化,一级动力学模型只能预测作物整个生育期土壤氮素矿化总的趋势,并不能反映某一阶段矿化量的变化,但模型能在种植作物以前估计出土壤氮素净矿化量,从这个意义上说,模型的预测作用仍是不可低估的。     

No‐tillage and fertilization management on crop yields and nitrate leaching in North China Plain

A field experiment was performed from 2003 to 2008 to evaluate the effects of tillage system and nitrogen management regimes on crop yields and nitrate leaching from the fluvo-aquic soil with a winter wheat (Triticum aestivum L.)–maize (Zea mays L.) double-cropping system. The tillage systems consisted of conventional tillage (CT) and no-tillage (NT). Three nitrogen management regimes were included: 270 kg N ha⁻¹ of urea for wheat and 225 kg N ha⁻¹ of urea for maize (U), 180 kg N ha⁻¹ of urea and 90 kg N ha⁻¹ of straw for wheat and 180 kg N of urea and 45 kg N ha⁻¹ of straw for maize (S), 180 kg N ha⁻¹ of urea and 90 kg N ha⁻¹ of manure for wheat and 180 kg N ha⁻¹ of urea and 45 kg N ha⁻¹ of manure for maize (M). An array of tension-free pan lysimeters (50 cm × 75 cm) were installed (1.2 m deep) to measure water flow and -N movement. No significant effect of the N management regime on yields of winter wheat and maize grain was found in the 5-year rotation. Tillage systems had significant influences on -N leaching from the second year and thereafter interacted with N management regimes on -N loads during all maize seasons. The average yield-scaled -N leaching losses were in order of CTS < NTS< CTU < NTU −1 for winter wheat system and from 0.99 (CTS) to 6.27 (NTM) kg N Mg⁻¹ for summer maize system for 5 rotation years. The results showed that CTS decreased the yield-scaled -N leaching losses while sustaining crop grain yields. Considering the lower costs, NTS could be a potential alternative to decrease yield-scaled -N leaching losses and improve soil fertility while maintaining crop yield for the winter wheat–maize double-cropping systems in the North China Plain.