油菜绿色面积指数动态模拟模型

准确模拟绿色面积指数是作物生长模拟模型可靠预测作物生长和产量的关键。该研究的目的是以生理生态过程为基础,构建油菜(Brassica napus)叶面积指数和角果面积指数变化动态的模拟模型。油菜叶面积指数模型综合考虑了库或源限制下的叶面积增长模式,其中库限制下叶面积指数的增长呈指数方程,且受到温度、水分和氮素因子的影响;源限制下叶面积指数增长用比叶面积法来模拟。油菜角果面积指数由比角果面积和角果干物重来决定。比叶面积和比角果面积均为生理发育时间的函数。利用不同类型品种的播期试验及氮肥试验资料分别对模型进行了校正和检验,结果表明模型能较好地模拟不同条件下油菜叶面积指数和角果面积指数。     

氮素对日光温室独本菊品种‘神马’干物质分配影响的模拟

 为定量研究氮素对日光温室独本菊(Dendranthema morifolium)干物质分配的影响, 该研究以独本菊品种‘神马’为试验材料, 于2005年10月～2006年7月在北京日光温室内进行了不同定植期和不同氮素水平的栽培试验, 以生理辐热积为发育尺度, 定量分析了氮素对独本菊品种‘神马’干物质分配指数动态的影响, 建立了氮素对日光温室独本菊品种‘神马’干物质分配影响的模拟模型, 并用与建立模型相独立的数据对模型进行了检验。结果表明, 独本菊品种‘神马’叶片累积氮含量最大值出现在现蕾期, 现蕾期叶片累积氮含量适宜值为1.62 g•m^–2。模型对日光温室独本菊品种‘神马’各器官干重预测结果较好, 茎、叶和花干重的预测值与实测值之间基于1:1线的决定系数分别为0.94、0.97和0.94, 相对预测误差分别为10.3%、5.76%和4.02%。该研究建立的模型可以根据温室内的气温、太阳辐射、日长和现蕾期叶片累积氮含量预测日光温室独本菊品种‘神马’各个器官干重随生育时期的动态变化, 从而为日光温室独本菊品种‘神马’生产中氮素的优化管理提供决策支持。     

棉花花铃期短期干旱下氮素对干物质及氮素累积分配的影响

通过盆栽试验进行水分(正常灌水和干旱后复水)和施氮处理(0、240、480kgN·hm-2),研究花铃期短期干旱再复水后氮素对棉花各器官干物质重、氮素累积与分配及产量与品质的影响.结果表明:花铃期土壤干旱显著降低了棉株各器官的干物质重与氮素累积量,而增大了棉株各器官的氮素含量,同时亦降低了棉株干物质与氮素在叶片中的分配指数,但提高了在根系的分配指数,从而增大了根冠比;增施氮肥可以提高干旱条件下棉株的干物质重与氮素累积量,但亦增大水分胁迫指数.复水对干旱处理棉株生长具有明显的补偿效应,尤其是根系的干物质重与氮素累积量显著高于相应正常灌水处理,且增施氮肥可以提高棉株的补偿效应.花铃期干旱结束时与复水后第10天,干旱处理棉株均以240kgN·hm-2水平下的生殖器官干物质重与分配指数最高,而根冠比最小,地上部与地下部生长最为协调,最终籽棉产量最高、纤维品质最优;而施氮不足(0kgN·hm-2)或过量(480kgN·hm-2)均不利于棉花产量的提高与纤维品质的改善.     

FACE水稻干物质积累与分配模型

借助中国唯一的FACE技术平台,通过设置不同的N肥处理,研究了FACE条件下水稻干物质积累及分配动态的模拟模型.模型以生理发育时间为驱动因子,以CO₂浓度函数为主要影响因子,同时引入N素影响因子调节干物质的积累与各器官分配指数.模拟结果表明,随着大气CO₂浓度的增加,水稻地上部总干物重显著增加,叶干重分配指数下降,穗干重分配指数基本不变,茎干重分配指数前期增加,后期持平.通过不同年份试验数据对模型的验证,预测根均方差（RMSE）较小,且相关系数均达到了极显著水平.表明模型拟合程度高,具有较好的适应性和预测性.     

基质水势对切花百合植株干物质分配影响的预测模型

干物质分配与转移是观赏植物外观品质形成的基础,受水分影响极大.本文以切花百合品种‘索邦’为试验材料,于2009年3月至2010年1月在南京的连栋温室内开展了不同定植期和不同水分处理的栽培试验,定量分析了不同定植期和不同水分处理条件下切花百合干物质分配和转移的变化规律,以及基质水势对百合地上部和地下部各器官(花、茎、叶、鳞茎、茎生根)干物质分配指数的动态影响,并确定了切花百合正常生长的临界基质水势,最终建立了基质水势对切花百合植株干物质分配影响的动态预测模型.结果表明:本文所建模型对百合各器官(花、茎、叶、鳞茎、茎生根)干质量的预测效果较好,模型对花、茎、叶、鳞茎、茎生根干质量的预测值与实测值之间的决定系数分别为0.96、0.95、0.86、0.95、0.85,预测相对标准误分别为19.2％、12.4％、19.4％、12.2％、31.7％.-15 kPa可作为切花百合‘索邦’水分管理的临界水势.     

不同氮效率油菜品种在常氮和缺氮条件下碳累积量、产量及品质比较

以氮高效品种27号与氮低效品种6号为试验材料,在常氮与氮胁迫两种供氮情况下,研究不同品种油菜叶片及角果、角果皮与籽粒中有机碳、产量与籽粒油分的变化及差异。结果表明,氮高效品种27号籽粒产量、收获指数、籽粒油分高于氮低效品种6号;在常氮(含KNO3 102 g·L-1与Ca(NO3)2·4H2O 236 g·L-1)和缺氮(含KNO3 34 g·L-1与Ca(NO3)2·4H2O 78.67 g·L-1)水平下,品种27号在抽薹期、花期与角果期,根和叶有机碳与干物质大于品种6号,收获期根有机碳与干物质小于品种6号。收获期缺氮时,品种27号叶干物质与有机碳较高。生殖生长期,品种27号的花、角果、籽粒有机碳与干物质积累较品种6号强,而营养生长期茎有机碳及干物质较低,在角果期开始增强。总之,氮高效品种27号生长前期碳素积累强,生长后期生殖器官中碳素及干物质积累较强,茎中转运较强。     

花期渍水逆境下氮素对油菜产量及氮肥利用效率的影响

温室盆栽试验条件下,设置渍水和对照2个水分处理,每个水分处理下设置3个施氮水平(0.05、0.2、0.3 g N·kg^-1土),研究了花后渍水逆境下氮素营养对两个氮高效基因型‘Monty’、‘湘油15’和两个氮低效基因型‘R210’、‘Bin270’油菜产量、产量性能及氮肥利用效率的影响.结果表明:与对照相比,花后渍水处理显著降低了油菜的单株角果数、千粒重、每角粒数和籽粒产量.在适宜水分条件下,增施氮肥显著增加了油菜籽粒产量,而在渍水逆境处理下,增施氮肥对油菜籽粒产量的形成贡献不大.氮高效基因型较氮低效基因型对花后渍水逆境下的籽粒灌浆充实具有一定的促进作用.在同一水分处理下,花后渍水明显降低了油菜氮肥利用率、氮肥偏生产力、氮肥农学利用率、氮素吸收效率和氮收获指数,渍水显著影响了不同基因型油菜的氮素吸收利用能力,而氮高效基因型在渍水逆境下较氮低效基因型更有利于将氮素转运、再分配到角果中,提高籽粒生产效率.油菜产量性能参数存在显著的水氮互作效应,水分、氮肥及水氮互作对油菜籽粒产量和产量性能参数的影响因基因型的不同而异.     

基于水分控制的切花百合生长预测模型

光合作用与干物质生产是观赏植物外观品质形成的基础。水分是影响植物光合作用与干物质生产的重要因子。为定量研究水分对切花百合光合作用与干物质生产的影响,以切花百合品种‘索邦’(Lilium‘Sorbonne’)为试验材料,于2009年3月至2010年1月在南京的连栋温室内开展了不同定植期和不同水分处理的栽培试验,以基于光温的温室花卉生长动态预测模型为基础,定量分析了不同定植期和不同水分处理条件下切花百合叶面积指数、光合速率和干物质生产的动态影响,并确定了切花百合正常生长的临界基质水势,建立了基质水势对切花百合光合速率和干物质生产影响的动态预测模型。结果表明,本文所建模型对切花百合叶片最大总光合速率和植株总干质量的预测效果较好,模型对叶面积指数、叶片最大总光合速率和植株干物质量的预测值与实测值之间的决定系数(r2)分别为0.97,0.96,0.94,相对根均方差(rRMSE)分别为7.12%、4.37%、11.14%。该模型能较好地预测水分对切花百合叶片最大总光合速率和植株总干质量的动态影响,可为进一步优化切花百合生产的水分管理提供决策支持。     

华北夏玉米干物质分配系数对干旱胁迫的响应

干物质分配系数反映作物各器官干物质的分配与积累,研究干物质分配系数对干旱胁迫的响应,是研究干旱胁迫对作物生长发育影响的基础.本文基于华北夏玉米主产省山东、河北和山西3个试验点2013—2015年田间水分控制试验资料,建立了夏玉米苗期、抽雄期、灌浆期3个主要发育阶段叶、茎、穗的干物质分配系数与土壤相对湿度的定量关系模型,分析了叶、茎、穗干物质分配系数对不同程度干旱胁迫的响应.结果表明: 3个阶段叶、茎、穗的干物质分配系数与土壤相对湿度均呈显著的一元二次关系.干旱胁迫下,叶片向外转运的干物质相对减少,叶干物质分配比例增加,并且在轻、中度干旱胁迫时的灌浆期(叶干物质分配系数增加0.04~0.09)以及重度干旱胁迫时的抽雄期(叶干物质分配系数增加0.17)响应最敏感.穗干物质分配系数对干旱胁迫表现为负响应,干旱胁迫越严重,分配系数越小,轻-重度干旱胁迫使穗干物质分配系数减小0.08~0.34.茎干物质分配系数对干旱胁迫的响应总体表现为灌浆期(正响应)＞抽雄期(负响应)＞苗期(负响应).     

油菜终花后角果和叶片光合对籽粒产量和品质的影响

以‘秦优7号’油菜品种为材料,设置叶片和角果遮光及摘除叶片处理,通过田间试验测定分析终花后角果和叶片的光合特性及其对籽粒产量、含油量及脂肪酸组成的影响。结果显示:(1)终花后油菜角果遮光使籽粒的千粒重、产量、含油量分别显著降低54.7%、62.1%、44.2%,且籽粒中硫甙含量及脂肪酸中棕榈酸、硬脂酸含量显著升高,亚麻酸含量显著降低。(2)叶片遮光和摘除叶片分别显著降低角粒数11.7%、11.3%,降低籽粒千粒重22.5%、17.9%,单株产量分别降低35.3%、44.7%,使籽粒脂肪酸中亚油酸、亚麻酸等含量显著增加,但对籽粒含油量无显著影响。(3)终花后油菜绿色角果皮最大面积是绿叶面积的1.54倍,角果叶绿素a、b以及类胡萝卜素含量显著低于叶片,但角果的净光合速率、蒸腾速率显著高于叶片;且角果层的光辐射强度显著高于角果层下的叶片层;角果响应光辐射强度的光补偿点、光饱和点均显著高于叶片;即角果能够适应较高强度光辐射环境。研究发现,油菜结角期角果层接受大部分光辐射,角果的光合活性显著高于叶片,是主要的光合器官,角果光合状况对籽粒产量、含油量及脂肪酸组成有显著影响。     

Influence of sowing windows and genotypes on growth,radiation interception,conversion efficiency and yield of guar

Crop growth largely depends on radiation. Radiation is the main impetus for photosynthesis and movement of photosynthates from source to sink. Therefore, identification of the optimum sowing windows and suitable cultivars for efficient utilization of radiation is of prime importance. A field study was conducted in red clay soil during 2014 and 2015 Kharif season and the treatments consisted of three genotypes and three sowing windows by using randomized complete block design with three replications. The effect of genotypes and sowing windows was found significant with respect to number of trifoliate leaves, leaf area ratio, dry matter production, grain numbers, pod length, test weight, grain yield, and stover yield of guar during 2014 as compared to 2015 sown crop. Statistically significant plant height, number of trifoliate leaves, number of branches, leaf area ratio, absolute growth rate, leaf area index, dry matter, grain number, pod length, grain yield, stover yield and a higher cumulative radiation interception were recorded with 15th August sown crop as compared to other sowing windows. The plant height, number of trifoliate leaves, number of branches, leaf area ratio, absolute growth rate, leaf area index, dry matter, grain number, pod length, grain yield, stover yield and maximum cumulative interception of radiation were significant with RGC-1003 as compared to RGC-936 and HG-365. It is observed that the incident PAR to dry matter accumulation conversion efficiency was varied with cultivars and different sowing windows which ranges from 0.74 g MJ⁻¹ to 0.79 g MJ⁻¹.     

Nitrogen Uptake and Plant Growth II. An Empirical Model of Vegetative Growth and Partitioning

An empirical model of vegetative plant growth is presented.The model is based on experimental data on Polygonum cuspidatum,which showed (1) that the partitioning of dry matter and nitrogenamong organs was linearly related to the nitrogen concentrationof the whole plant and (2) that leaf thickness was negativelycorrelated with leaf nitrogen concentration. The model properlydescribes the behaviour of plants. Steady-state solutions ofthe model give the relative growth rate, specific leaf weight,and partitioning of dry matter and nitrogen among organs withthe net assimilation rate and the specific absorption rate asenvironmental variables. The effect of nitrogen removal on drymatter and nitrogen partitioning was examined as non-steady-statedynamic solutions of the model. The model predicted not onlyreduced leaf growth and enhanced root growth but also a fluxof nitrogen from the leaf to the root, which agreed with theexperimental results. Mathematical model, partitioning of dry matter and nitrogen, plant nitrogen, relative growth rate, shoot: root ratio, specific leaf weight     

Pre-flowering Growth and Development of the Inflorescences of Maize: II. ACCUMULATION AND PARTITIONING OF DRY MATTER AND NITROGEN BY INFLORESCENCES

The accumulation and partitioning of dry matter and nitrogenwere examined in the developing tassel and two uppermost earshoots of field-grown maize under varying levels of appliednitrogen and times of sowing. Accumulation of dry matter and nitrogen within an axillary branchalways favoured the ear over the husk and shank. Dry matterand nitrogen accumulated faster in the first ear than in thetassel or second ear and the partitioning between inflorescencesof dry matter and nitrogen was not affected by treatment. Therelative rate of growth, RGR(dry matter), of the first and secondear shoots increased by up to 42% at high levels of appliednitrogen and with early sowing. In contrast, the relative rateof accumulation of nitrogen (RNAR) was not sensitive to N supply,although it was reduced, on average, by 22% at the late timeof sowing. We conclude that accumulation, but not partitioning, of drymatter and nitrogen between developing inflorescences of maizeare altered by nitrogen application, time of sowing, and positionof the inflorescence on the stem. Key words: Maize, N-application, partitioning, inflorescence, sowing time     

基于叶片干物质的滴灌玉米临界氮稀释曲线构建

建立宁夏引黄灌区滴灌玉米临界氮浓度稀释曲线,采用临界氮浓度模型对滴灌玉米氮营养状况进行分析,探讨基于此模型推导的氮营养指数用于诊断氮营养的可行性,为实现滴灌玉米氮肥精准管理和生态环境保护提供理论参考。试验以‘天赐19’玉米为材料,设置6个氮素水平(0、90、180、270、360和450 kg·hm^-2),在2年田间定位试验的基础上构建基于叶片干物质(LDM)的滴灌玉米临界氮浓度(N_c)稀释曲线和氮营养指数模型。结果表明: 1)滴灌玉米叶片干物质和氮浓度之间呈负幂函数关系,其模型表达式分为2部分: 当LDM<1.15 t·hm^-2时,N_c=3.2%;当LDM≥1.15 t·hm^-2时,N_c=3.29LDM^-0.29;2)拟合模型的评价指标均方根误差(RMSE)和标准化均方根误差(n-RMSE)分别为0.203、8.0%,年度间具有较好的稳定性;3)不同氮素处理下,氮营养指数(NNI)在0.47~1.44。不同生长阶段NNI与产量呈显著正相关,与氮肥农学利用效率呈显著负相关,故NNI可进一步解释滴灌玉米在限氮和非限氮条件下的产量变化。本研究基于叶片干物质构建的临界氮浓度稀释曲线可在滴灌玉米拔节期至吐丝期提供准确的氮素营养状况估测。     

温室番茄干物质分配与产量的模拟分析

根据试验资料及温室番茄(Lycopersicon esculentum)作物的生长特性,构建了基于分配指数(Partitioning index,PI)和收获指数(Harvest index,HI)与辐热积(Product of thermal effectiveness and PAR,TEP)关系的番茄干物质分配和产量预测的数学模型,并利用不同品种、基质和地点的试验资料对模型进行检验.模型对番茄地上部分干重、根系干重、茎干重、叶片干重和果干重的预测结果与1∶1直线之间的决定系数(Coefficient of determination,R²)分别为0.95、0.57、0.82、0.79和0.93;统计回归标准误差(Root mean squared error,RMSE)分别为647.0、78.1、279.0、496.9和381.8 kg·hm^-2;对产量的预测结果与1∶1直线之间的R²和RMSE分别为0.88和5 828.5 kg·hm^-2;不仅预测精度较高,且参数少、用户易于获取,为温室番茄模型应用于温室番茄生产的优化管理奠定了基础.     

Simulation of leaf area development based on dry matter partitioning and specific leaf area for cut chrysanthemum

This work aims to predict time courses of leaf area index (LAI) based on dry matter partitioning into the leaves and on specific leaf area of newly formed leaf biomass (SLA(n)) for year-round cut chrysanthemum crops. In five glasshouse experiments, each consisting of several plant densities and planted throughout the year, periodic destructive measurements were conducted to develop empirical models for partitioning and for SLA(n). Dry matter partitioning into leaves, calculated as incremental leaf dry mass divided by incremental shoot dry mass between two destructive harvests, could be described accurately (R(2 )= 0.93) by a Gompertz function of relative time, R(t). R(t) is 0 at planting date, 1 at the start of short-days, and 2 at final harvest. SLA(n), calculated as the slope of a linear regression between periodic measurements of leaf dry mass (LDM) and LAI, showed a significant linear increase with the inverse of the daily incident photosynthetically active radiation (incident PAR, MJ m(-2 )d(-1)), averaged over the whole growing period, the average glasshouse temperature and plant density (R(2 )= 0.74). The models were validated by two independent experiments and with data from three commercial growers, each with four planting dates. Measured shoot dry mass increase, initial LAI and LDM, plant density, daily temperature and incident PAR were input into the model. Dynamics of LDM and LAI were predicted accurately by the model, although in the last part of the cultivation LAI was often overestimated. The slope of the linear regression of simulated against measured LDM varied between 0.95 and 1.09. For LAI this slope varied between 1.01 and 1.12. The models presented in this study are important for the development of a photosynthesis-driven crop growth model for cut chrysanthemum crops.     

Dry matter and nitrogen accumulation and partitioning in selected soybean genotypes of different derivation

Summary Experiments were conducted to determine if changes in the accumulation and partitioning of dry matter (DM) and nitrogen (N) in soybean [Glycine max (L.) Merr.] were associated with agronomic improvements and to assess the degree of genetic variation present for these traits. Fifteen maturity group II soybean genotypes including three ancestral cultivars, three modern cultivars, and nine agronomically superior plant introductions (PI's) were grown in replicated tests at four locations in the eastern U.S. The DM and N of stems, pod walls, and seeds were determined at maturity, and the apparent harvest indices (HI) and the apparent nitrogen harvest indices (NHI) were calculated. Pod DM partitioning was calculated as the ratio of seed DM to total pod DM and pod N partitioning was the ratio of seed N to total pod N. The mean DM accumulation of the modern cultivars was significantly greater than that of the ancestral cultivars and PI's. The apparent HI and the pod DM partitioning of both the modern and ancestral cultivars were significantly higher than that of the PI's. The three modern cultivars demonstrated the highest N accumulation. As a group, the modern cultivars consistently showed maximal accumulation and partitioning of DM and N suggesting that these physiological traits are associated with agronomic improvement. No individual PI was found to possess DM or N accumulation or partitioning which significantly exceeded the best modern cultivar or ancestral cultivar, indicating that genotypes with accumulation or partitioning characteristics which exceed available germplasm may be difficult to identify. Seed yield was correlated (P<0.05) with both DM (r=0.61) and N (r=0.57) accumulation.     

播期对春小麦生长发育及产量的影响

为了给陇中半干旱区春小麦高产栽培提供依据,2010年在甘肃定西进行了春小麦分期播种试验,并对不同播期条件下春小麦生长发育及产量形成进行了分析。结果表明:随着播期的推迟,春小麦播种-抽穗期日数减少、全生育期明显缩短;5月下旬之前,越早播种的春小麦LAI越大,5月下旬之后,播种愈晚春小麦LAI越大。早播春小麦LAI峰值靠前,晚播峰值滞后;6月下旬之前,播期早的春小麦叶绿素含量高于播期晚的,6月下旬之后播期愈早叶绿素含量下降愈快;不同播期春小麦群体生长率和净同化率在孕穗-抽穗期后差异显著,表现为3月18日播期最大,4月7日播期最小。各播期干物质累积在拔节期后表现为快速递增趋势。在拔节期前,早播处理的干物质积累速率较慢。随着播期的推迟,单株干物质最大积累速率出现时间提前,籽粒最大灌浆速率出现时间推迟,千粒重表现为先升后降;灌浆3个阶段各参数受播期影响比较显著;早播春小麦产量最高。