北方旱地土壤氮素平衡

北方大部分地区的旱地土壤中,农业氮素一般表现亏损,平衡强度约87%;园田土壤氮素略有盈余,平衡强度约123%.~(15)示踪研究表明,旱地土壤主要作物氮素利用率平均为27.04%,土壤残留24.79%,亏缺损失48.17%.园田主要蔬菜氮素和用率平均为29.11%,土壤残留22.67%,亏缺损失48.23%,其间差异很小.北方旱地施用铵态氮化肥主要损失是氨的挥发.影响氨挥发的因素有风速、温度、土壤水分、土壤质地、化肥品种.氮肥深施是防止氨挥发的有效方法.     

Analysis of the uncertainty associated with the estimation of nitrogen losses from farming systems

This work describes the analysis of the uncertainty linked to the annual direct and indirect losses of different nitrogenous compounds at the scale of a group of farms. The nitrogen (N) forms taken into account are: ammonia (NH₃), nitric oxide (NO), nitrous oxide (N₂O), dinitrogen (N₂) and nitrate (NO₃). The gaseous N emissions for the different components of the farms are estimated with a selection of adapted emission factors. The NO₃ losses at the farm scale are calculated as the difference between the surplus of the farm-gate N balance and the gaseous N emissions.     

Evaluation of the RZWQM-CERES-Maize hybrid model for maize production

The root zone water quality model (RZWQM) was developed primarily for water quality research with a generic plant growth module primarily serving as a sink for plant nitrogen and water uptake. In this study, we coupled the CERES-Maize Version 3.5 crop growth model with RZWQM to provide RZWQM users with the option for selecting a more comprehensive plant growth model. In the hybrid model, RZWQM supplied CERES with daily soil water and nitrogen contents, soil temperature, and potential evapotranspiration, in addition to daily weather data. CERES-Maize supplied RZWQM with daily water and nitrogen uptake, and other plant growth variables (e.g., root distribution and leaf area index). The RZWQM-CERES hybrid model was evaluated with two well-documented experimental datasets distributed with DSSAT (Decision Support System for Agrotechnology Transfer) Version 3.5, which had various nitrogen and irrigation treatments. Simulation results were compared to the original DSSAT-CERES-Maize model. Both models used the same plant cultivar coefficients and the same soil parameters as distributed with DSSAT Version 3.5. The hybrid model provided similar maize prediction in terms of yield, biomass and leaf area index, as the DSSAT-CERES model when the same soil and crop parameters were used. No overall differences were found between the two models based on the paired t test, suggesting successful coupling of the two models. The hybrid model offers RZWQM users access to a rigorous new plant growth model and provides CERES-Maize users with a tool to address soil and water quality issues under different cropping systems.     

两种形态氮源条件下磷对大豆结瘤固氮的影响

用营养液培养大豆7周,研究两种氮源条件下,磷对大豆结瘤固氮的影响.在本试验的各取样时期,随营养液中磷水平的增加,生物固氮植株的根瘤数增加较多,尤其是处理后第6周,磷对根瘤形成的影响最大.磷对硝态氮处理根瘤数的影响不大,但本试验条件下,在16μmol/L磷水平,根瘤数较多.硝态氮处理根瘤数远没有生物固氮处理多,表现出氮素对大豆结瘤的抑制作用,导致根瘤固定的氮量减少.因此,硝态氮植株体内含氮量随磷水平的增加而降低,而生物固氮植株增加.生物固氮处理根中N/P与根瘤数之间存在显著的负相关关系,r=-0.5816*,硝态氮处理根中N/P与根瘤数之间不相关.     

氮磷钾底肥对大豆蛋白质含量的效应

采用正交回归旋转设计方法,建立了氮、磷、钾肥对大豆蛋白质含量的综合作用模型.依据该模型探讨氮、磷、钾肥对大豆蛋白质含量影响的规律.氮、磷、钾肥对大豆蛋白质含量的单因素效应、二因素互作效应受到其它因素水平的影响.氮肥对蛋白质含量的影响均为负效应,降低速度随着氮肥编码值增高而加快.磷肥对蛋白质含量的作用有正有负.钾肥对蛋白质含量的作用为负效应,其降低幅度随钾的增加而提高.施尿素量为1.93～4.70g/盆,施重过磷酸钙量为8.13～20.59g/盆,施硫酸钾量为1.27～3.37g/盆,采用这个比例施肥有95%的可能使蛋白质含量高于43.5%.     

不同施N水平纽荷尔脐橙叶绿素含量的季节变化

以1年生盆栽枳砧纽荷尔脐橙为试材,研究不同施N水平对叶片N含量,春梢、夏梢和秋梢落叶率,以及春梢、夏梢和秋梢叶绿素含量季节变化的影响。结果显示,施N植株前期落叶率略高于未施N植株,后期无显著差异;叶片N含量与施N量存在极显著正相关关系（r=0.97）;施N处理显著提高了不同枝梢叶片的叶绿素含量,并且在整个测定时期内使叶绿素含量维持在较为稳定的水平;单株施N量高于6.5 g时叶绿素含量不再显著增加,但更有利于维持叶绿素含量的周年稳定;对照（不施N）的不同枝梢叶片叶绿素含量从当年9月开始明显下降,翌年3月出现锐降,而施N植株仅略微下降。由此可见,N不仅可提高叶绿素含量且可减少其季节性变化幅度。     

不同氮肥处理下高温胁迫对夏玉米产量及叶片超微构造的影响

以郑单958为材料,研究高温胁迫对夏玉米产量及叶片超微构造的影响。结果表明,高温处理缩短夏玉米的生育天数,降低夏玉米产量及叶绿素含量。随氮肥增加,高温处理对玉米产量的影响先降低后升高(在310.5 kg/hm^2氮肥下,高温处理玉米产量的降低达到27.2%、31.1%)。高温处理较对照维管束鞘细胞变大,高温处理维管束鞘细胞内的叶绿体出现淀粉粒,对照处理维管束鞘细胞内的叶绿体没有出现淀粉粒。高温线粒体及细胞核(被)膜开始解离,对照处理线粒体及细胞核(被)膜完整,说明高温条件下,玉米对氮的耐受力降低。高温处理叶绿体数、叶绿体基粒数减少及基粒片层数减少,叶绿体面积及叶绿体长/宽比值变小,高温处理较对照线粒体数先增加后减少。高温处理与对照叶肉细胞叶绿体内均未发现淀粉粒。     

汾渭平原农户冬小麦氮磷养分投入调查与分析

为明确汾渭平原农户冬小麦施肥现状,并指导农户合理施肥,在汾渭平原冬小麦种植区选取22个区/县,连续2年进行农户冬小麦产量及氮、磷养分投入调查。结果表明,汾河平原和渭河平原农户冬小麦平均产量分别为6 949和6 442 kg·hm^-2,其中中等产量水平（5 500 kg·hm^-2）以上的农户超过80%。汾河平原农户冬小麦N和P₂O₅的平均投入量分别为272.6和139.1 kg·hm^-2,施氮不足、适中和过量的农户分别占11.84%、23.68%和64.47%,施磷不足、适中和过量的农户分别占14.03%、7.89%和78.07%。渭河平原农户N和P₂O₅的平均投入量分别为196.3和147.2 kg·hm^-2,施氮不足、适中和过量的农户分别占 28.63%、31.97%和39.40%,施磷不足、适中和过量的农户分别占5.95%、14.50%和79.56%。汾河平原农户冬小麦氮肥基肥和追肥比例分别为60.3%和39.7%,而渭河平原农户冬小麦氮肥基肥和追肥比例分别为 97.3%和2.7%。此外,汾河平原农户冬小麦N、P₂O₅的平均偏生产力分别为30.4和59.6 kg·kg^-1,渭河平原农户冬小麦N、P₂O₅的平均偏生产力分别为38.4和56.1 kg·kg^-1。总之,在汾渭平原农户冬小麦种植过程中,氮、磷肥过量施用依然严重,导致肥料利用率低,因此,未来需进一步加强对农民的宣传培训,使其科学合理施肥,促进农业绿色发展。     

Relay-intercropping soybean with maize maintains soil fertility and increases nitrogen recovery efficiency by reducing nitrogen input

Optimized nitrogen(N)management can increase N-use efficiency in intercropping systems.Legume-nonlegume intercropping systems can reduce N input by exploiting biological N fixation by legumes.Measurement of N utilization can help in dissecting the mechanisms underlying N uptake and utilization in legume-nonlegume intercropping systems.An experiment was performed with three planting patterns:monoculture maize(MM),monoculture soybean(SS),and maize-soybean relay intercropping(IMS),and three N application levels:zero N(NN),reduced N(RN),and conventional N(CN)to investigate crop N uptake and utilization characteristics.N recovery efficiency and 15N recovery rate of crops were higher under RN than under CN,and those under RN were higher under intercropping than under the corresponding monocultures.Compared with MM,IMS showed a lower soil N-dependent rate(SNDR)in 2012.However,the SNDR of MM rapidly declined from 86.8%in 2012 to 49.4%in 2014,whereas that of IMS declined slowly from 75.4%in 2012 to 69.4%in 2014.The interspecific N competition rate(NCRms)was higher under RN than under CN,and increased yearly.Soybean nodule dry weight and nitrogenase activities were respectively 34.2%and 12.5%higher under intercropping than in monoculture at the beginning seed stage.The amount(Ndfa)and ratio(%Ndfa)of soybean N2 fixation were significantly greater under IS than under SS.In conclusion,N fertilizer was more efficiently used under RN than under CN;in particular,the relay intercropping system promoted N fertilizer utilization in comparison with the corresponding monocultures.An intercropping system helps to maintain soil fertility because interspecific N competition promotes biological N fixation by soybean by reducing N input.Thus,a maize-soybean relay intercropping system with reduced N application is sustainable and environmentally friendly.     

Identification and evaluation of high nitrogen nutrition efficiency in rapeseed (Brassica napus L.) germplasm

To establish identification and evaluation methods of N (nitrogen) absorption and utilization of rapeseed (Brassica napus L.), difference of N nutrition efficiency (NNE) among rapeseed germplasms and relationship between NNE and plant traits under various N application rates were analyzed in this research. Pot cultivating experiments were conducted to investigate NNE with 3 ​N application rates in soil (0.05, 0.2 and 0.3 ​g/kg). A total of 12 rapeseed germplasms were planted, nitrogen absorption efficiency (NAE) and nitrogen utilization efficiency (NUE) in seedling stage, bolting stage, initial flowering stage, final flowering stage, and maturity stage were obtained. Results showed that bolting stage was the best period for NAE identification and evaluation. Low N application rate in soil (0.05 ​g/kg) was the best for NAE, and the indirect indexes were basal stem diameter, plant root dry weight and above ground plant dry weight. Maturity stage was the best period for NUE identification and evaluation. High N application rate in soil (0.3 ​g/kg) was the best for NUE, and indirect indexes were above ground plant dry weight and basal stem diameter. N application rates of 0.05 ​g/kg in soil was the best for nitrogen harvest index at maturity stage, and indirect indexes was number of pods per plant. Plant traits of rapeseed germplasms affected NNE. Higher basal stem diameter, plant root dry weight and above ground plant dry weight at bolting stage under low N application rate were important characteristics of N absorption in rapeseed. Higher above ground plant dry weight and basal stem diameter at maturity stage under high N application rate were important characteristics of N utilization. Higher number of pods per plant at maturity stage under lowe N application rate was an important characteristic of N harvest index. These results provided a reliable index for N management and provided theoretical basis for guiding rapeseed breeding.