高温胁迫对猕猴桃叶片叶绿素荧光特性的影响

为探讨高温对猕猴桃叶片光合机构的影响,建立基于叶绿素荧光反应的高温热害识别指标,利用叶绿素快速荧光诱导动力学分析技术,研究不同温度胁迫下猕猴桃叶片8类叶绿素荧光的变化特征。结果表明：单位面积捕获的光能、单位面积有活性的反应中心数量、300 μs处相对可变荧光强度差值在30℃≤T≤54℃时均受温度胁迫影响,属光系统Ⅱ敏感位点参数,其中单位面积捕获的光能、单位面积有活性的反应中心数量随温度升高呈直线下降趋势,300 μs处相对可变荧光强度差值随温度升高呈指数上升趋势;初始荧光、最大荧光、最大光化学效率、单位面积的热耗散、单位面积用于电子传递的能量在较低温度胁迫下稳定少变,在较高温度胁迫下变化加剧,属光系统Ⅱ次敏感位点参数;多数叶绿素荧光参数在39℃和45℃存在两个突变临界点;叶绿素各荧光参数特征显示,猕猴桃叶片在30℃≤T < 39℃出现轻度温度胁迫,39℃≤T < 45℃出现中度温度胁迫,T≥45℃出现重度温度胁迫。     

设施芹菜光合特性对寡照胁迫的响应

以芹菜品种＂津南实芹1号＂为试材,于2011年3～4月在南京信息工程大学人工控制温室设计寡照试验,测定不同寡照处理和恢复处理的光合参数及荧光参数。结果表明：随着寡照天数的增加,芹菜叶片的最大光合速率、光饱和点、光能初始利用效率显著低于对照,光补偿点逐渐增加;不同的寡照处理下,芹菜叶片最大光合速率与胞间CO2浓度关系最密...     

淹涝胁迫对水稻植株叶片光合性能的影响

为提高水稻作物生长模型中淹涝胁迫对水稻生长和产量影响的定量评估能力,通过开展水稻盆栽淹涝试验,研究了不同淹涝胁迫程度对粳稻和籼稻植株叶片光合性能的影响,并将两者之间的关系进行了定量化,结果表明:1)两种水稻植株叶片的光量子效率AQE、最大光合速率P_m均随淹涝天数的增加而明显下降,全淹处理的下降幅度较大,受全淹处理8天后平均下降幅度近五成,而半淹处理的下降幅度较小,半淹处理8天后平均降幅约一成左右;叶片基础荧光F_0、最大荧光产额F_m和最大光化学效率F_v/F_m也均随着淹涝胁迫天数的增加出现不同程度的降低。2)植株叶片光量子效率和最大光合速率随淹涝深度和淹涝天数变化可用定量关系模型y=1-aH-bH~3T来描述,用独立的试验资料对该模型进行检验后表明,模型的模拟值与实测值有很好的一致性,两者的相关系数高、RMSE值低,模拟效果令人满意。3)全淹处理下,水稻植株叶片最大光合速率P_m和最大荧光产额F_m下降幅度具有较好的相关性,可运用荧光测定的信息来快速估计淹涝胁迫对水稻叶片光合速率影响的程度。本研究可为改进水稻模型中淹涝胁迫条件下的水稻干物质累积和产量的模拟提供依据。     

呼伦贝尔草原生长季叶绿素荧光的特征及其对气象条件变化的响应

在2022年生长季内,基于轨道植被观测仪(型号NZD-G1)对呼伦贝尔草原开展了日光诱导叶绿素荧光(Solar-Induce chlorophyll Fluorescence,SIF)的原位观测。相较于归一化植被指数,SIF的低频变化分量同样可以表征植物在生长季内的长势变化,而高频变化可以更清楚地监测植物内光合作用的生理过程,且其高频变化与气象条件密切相关。土壤水含量和SIF的关系是非线性的,当降水持续偏多导致土壤偏涝时,牧草的生理代谢减弱,光合作用减缓(SIF值偏低);当前期降水适量导致土壤湿润,且太阳辐射较强时,SIF值可以持续稳定在较高水平,植物光合作用旺盛,长势良好。而在生长季后期,偏凉的秋雨会显著降低植物的光合作用,且后期难以恢复。     

干旱胁迫对夏玉米叶片光合及叶绿素荧光的影响

选用华北地区大面积种植的夏玉米品种郑单958、承玉2号、鲁单981作为试验材料,通过研究干旱胁迫条件下的玉米叶片光合、叶绿素荧光等指标随着土壤水分的动态变化规律,以期为夏玉米干旱的生理生态变化监测及水分高效利用提供理论依据.研究发现,在土壤含水量70%左右时,随着土壤相对湿度的下降,上述3个夏玉米品种仍能保持其叶片水分状态.郑单958、承玉2号、鲁单981的叶片净光合速率在土壤水分中等条件下最大,分别为39.9、38.8、38.4 μmol CO2/m2 · s;在土壤相对湿度较低时,郑单958、承玉2号、鲁单981的叶片净光合速率下降趋势明显(P＜0.05).叶片水势变化规律为:在土壤相对湿度＞90%时,对水分胁迫郑单958、承玉2号不敏感,鲁单981敏感;在土壤相对湿度＜70%时,水分胁迫条件下承玉2号不敏感,而鲁单981、郑单958敏感.气孔导度(gs)变化规律:随着水分胁迫加剧,3个夏玉米品种气孔导度均下降,在土壤水分较高时,气孔导度变化规律不明显,在土壤水分较低时,气孔导度明显下降(P＜0.01),细胞间隙CO2浓度(Ci)随土壤水分胁迫加剧而上升.上述结果表明:与叶片的光合和水分状况相比,夏玉米的气孔对土壤水分的匮缺更为敏感.     

干旱胁迫对夏玉米叶片光合及叶绿素荧光的影响

选用华北地区大面积种植的夏玉米品种郑单958、承玉2号、鲁单981作为试验材料,通过研究干旱胁迫条件下的玉米叶片光合、叶绿素荧光等指标随着土壤水分的动态变化规律,以期为夏玉米干旱的生理生态变化监测及水分高效利用提供理论依据。研究发现,在土壤含水量70％左右时,随着土壤相对湿度的下降,上述3个夏玉米品种仍能保持其叶片水分状态。郑单958、承玉2号、鲁单981的叶片净光合速率在土壤水分中等条件下最大,分别为39．9、38．8、38．4μmolCO2／m^2·s;在土壤相对湿度较低时,郑单958、承玉2号、鲁单981的叶片净光合速率下降趋势明显（P〈0．05）。叶片水势变化规律为：在土壤相对湿度〉90％时,对水分胁迫郑单958、承玉2号不敏感,鲁单981敏感;在土壤相对湿度〈70％时,水分胁迫条件下承玉2号不敏感,而鲁单981、郑单958敏感。气孔导度（g1）变化规律：随着水分胁迫加剧,3个夏玉米品种气孔导度均下降,在土壤水分较高时,气孔导度变化规律不明显,在土壤水分较低时,气孔导度明显下降（P〈0．01）,细胞间隙CO2浓度（Ci）随土壤水分胁迫加剧而上升。上述结果表明：与叶片的光合和水分状况相比,夏玉米的气孔对土壤水分的匮缺更为敏感。     

温室黄瓜低温气象灾害指标

以黄瓜品种津优35号(Jingyou 35)为试材,于2011年设计不同低温（5、7、9、11 ℃,以25 ℃为对照）处理的人工环境控制试验,系统研究不同低温胁迫对黄瓜叶片光合作用特性及抗氧化酶活性的影响。结果表明：黄瓜叶片最大光合速率随低温胁迫程度的增加依次降低;在不同低温胁迫下,随胁迫时间的延长,黄瓜叶片光补偿点不断升高,光饱和点不断降低;在5 ℃、7 ℃和9 ℃低温处理下,随胁迫时间的延长,光系统Ⅱ最大光化学效率呈下降趋势,光化学淬灭不断降低,非光化学淬灭的变化趋势相反;黄瓜叶片中的超氧化物歧化酶活性随着处理温度的降低先升高后下降;过氧化物酶活性在9 ℃处理24 h后达到最高;过氧化氢酶活性随着处理温度的降低而升高;丙二醛含量大于对照,随胁迫程度的增加先升高,后略有下降。通过研究建立了温室黄瓜低温气象灾害指标,划分为4个等级,分别为轻度、中度、重度和极重,可为设施农业气象服务提供科学依据。     

叶绿素荧光遥感在陆地生态系统碳循环和陆气相互作用中的应用研究进展

陆地生态系统通过植被光合作用可以吸收约30％的人为碳排放,在全球碳循环、减缓大气二氧化碳浓度上升等方面具有重要作用。最近10年发展起来的日光诱导叶绿素荧光遥感技术,可以监测植被实际光合作用,为全球陆地生态系统碳循环的研究提供了新的思路和方法。本文回顾了叶绿素荧光遥感产品发展及其在陆地生态系统碳循环和陆气相互作用中的应用研究进展,特别是在全球植被总初级生产力估算和陆地生态系统碳循环模型发展方面的进展,并进一步讨论了该领域研究面临的挑战和未来的发展方向。     

大同颗粒物化学成分及其对北京影响

Atmospheric particle samples were collected at an urban site of Datong, Shanxi Province, during December 2004 and their element concentrations at different sizes were analyzed by particle-induced X-ray emission （PIXE）. Analysis of the observation data showed that particle pollution was heavy in winter at Datong and that concentrations of most elements were high in the coarse range. Factor analysis （FA） results indicated that the soil and dust, coal combustion dust, and industry dust are main sources for atmospheric particles in winter at Datong. The enrichment factors of element concentrations showed that particle pollution at Datong impacts the down-wind region--Beijing--in the dust season.     

基于3种遥感指数的东北春玉米干旱识别对比

以东北春玉米为研究对象,探究利用植被光合特性的日光诱导叶绿素荧光(solar-induced chlorophyll fluorescence,SIF)指数、近红外-短波红外波段构建的归一化差值水分指数(normalized difference water index,NDWI)和可见光-近红外波段构建的归一化差值植被指数(normalized difference vegetation index,NDVI)识别东北春玉米干旱的准确度和敏感度。研究发现：SIF指数、NDWI和NDVI对干旱识别准确度均超过80%,其中重度干旱准确度超过94%,且在春玉米苗期表现最佳;3种指数对比可知,SIF指数在春玉米干旱识别的准确度和敏感度方面均最佳,分别为89.27%和81.65%,NDWI敏感度次之,NDVI最差。表明基于光合特性的SIF指数在识别东北春玉米干旱方面优于基于地物光谱特性所构建的植被指数。     

AN INTEGRATION METHOD WITH FITTING CUBIC SPLINE FUNCTIONS TO A NUMERICAL MODEL OF 2ND-ORDER SPACE-TIME DIFFERENTIAL REMAINDER——FOR AN IDEAL GLOBAL SIMULATION CASE WITH PRIMITIVE ATMOSPHERIC EQUATIONS

In this paper,the forecasting equations of a 2nd-order space-time differential remainder are deduced from the Navier-Stokes primitive equations and Eulerian operator by Taylor-series expansion.Here we introduce a cubic spline numerical model(Spline Model for short),which is with a quasi-Lagrangian time-split integration scheme of fitting cubic spline/bicubic surface to all physical variable fields in the atmospheric equations on spherical discrete latitude-longitude mesh.A new algorithm of"fitting cubic spline—time step integration—fitting cubic spline—……"is developed to determine their first-and2nd-order derivatives and their upstream points for time discrete integral to the governing equations in Spline Model.And the cubic spline function and its mathematical polarities are also discussed to understand the Spline Model’s mathematical foundation of numerical analysis.It is pointed out that the Spline Model has mathematical laws of"convergence"of the cubic spline functions contracting to the original functions as well as its 1st-order and 2nd-order derivatives.The"optimality"of the 2nd-order derivative of the cubic spline functions is optimal approximation to that of the original functions.In addition,a Hermite bicubic patch is equivalent to operate on a grid for a 2nd-order derivative variable field.Besides,the slopes and curvatures of a central difference are identified respectively,with a smoothing coefficient of 1/3,three-point smoothing of that of a cubic spline.Then the slopes and curvatures of a central difference are calculated from the smoothing coefficient 1/3 and three-point smoothing of that of a cubic spline,respectively.Furthermore,a global simulation case of adiabatic,non-frictional and"incompressible"model atmosphere is shown with the quasi-Lagrangian time integration by using a global Spline Model,whose initial condition comes from the NCEP reanalysis data,along with quasi-uniform latitude-longitude grids and the so-called"shallow atmosphere"Navier-Stokes primitive equations in the spherical coordinates.The Spline Model,which adopted the Navier-Stokes primitive equations and quasi-Lagrangian time-split integration scheme,provides an initial ideal case of global atmospheric circulation.In addition,considering the essentially non-linear atmospheric motions,the Spline Model could judge reasonably well simple points of any smoothed variable field according to its fitting spline curvatures that must conform to its physical interpretation.     

Classification of Northeast China Cold Vortex Activity Paths in Early Summer Based on K-means Clustering and Their Climate Impact

The classification of the Northeast China Cold Vortex(NCCV)activity paths is an important way to analyze its characteristics in detail.Based on the daily precipitation data of the northeastern China(NEC)region,and the atmospheric circulation field and temperature field data of ERA-Interim for every six hours,the NCCV processes during the early summer(June)seasons from 1979 to 2018 were objectively identified.Then,the NCCV processes were classified using a machine learning method(k-means)according to the characteristic parameters of the activity path information.The rationality of the classification results was verified from two aspects,as follows:(1)the atmospheric circulation configuration of the NCCV on various paths;and(2)its influences on the climate conditions in the NEC.The obtained results showed that the activity paths of the NCCV could be divided into four types according to such characteristics as the generation origin,movement direction,and movement velocity of the NCCV.These included the generation-eastward movement type in the east of the Mongolia Plateau(eastward movement type or type A);generation-southeast longdistance movement type in the upstream of the Lena River(southeast long-distance movement type or type B);generationeastward less-movement type near Lake Baikal(eastward less-movement type or type C);and the generation-southward less-movement type in eastern Siberia(southward less-movement type or type D).There were obvious differences observed in the atmospheric circulation configuration and the climate impact of the NCCV on the four above-mentioned types of paths,which indicated that the classification results were reasonable.     

Phase Two of the Integrative Monsoon Frontal Rainfall Experiment (IMFRE-II) over the Middle and Lower Reaches of the Yangtze River in 2020

Phase Two of the Integrative Monsoon Frontal Rainfall Experiment(IMFRE-II)was conducted over the middle and lower reaches of the Yangtze River during the period 16 June to 19 July 2020.This paper provides a brief overview of the IMFRE-II field campaign,including the multiple ground-based remote sensors,aircraft probes,and their corresponding measurements during the 2020 mei-yu period,as well as how to use these numerous datasets to answer scientific questions.The highlights of IMFRE-II are:(1)to the best of our knowledge,IMFRE-II is the first field campaign in China to use ground-based,airborne,and spaceborne platforms to conduct comprehensive observations over the middle and lower reaches of the Yangtze River;and(2)seven aircraft flights were successfully carried out,and the spectra of ice particles,cloud droplets,and raindrops at different altitudes were obtained.These in-situ measurements will provide a“cloud truth”to validate the ground-based and satellite-retrieved cloud and precipitation properties and quantitatively estimate their retrieval uncertainties.They are also crucial for the development of a warm(and/or cold)rain conceptual model in order to better understand the cloud-to-rain conversion and accretion processes in mei-yu precipitation events.Through an integrative analysis of ground-based,aircraft,and satellite observations and model simulations,we can significantly improve our cloud and precipitation retrieval algorithms,investigate the microphysical properties of cloud and precipitation,understand in-depth the formation and dissipation mechanisms of mei-yu frontal systems,and improve cloud microphysics parameterization schemes and model simulations.     

CHARACTERISTICS OF TROPICAL CYCLONES IMPACTING A NUCLEAR POWER PLANT IN SOUTHERN FUJIAN AND ESTIMATE OF MINIMUM CENTRAL PRESSURE

Based on tropical cyclone (TC) data for the period 1949 to 2008 and following the Gumbe-I method, Pearson-Ⅲ method and determinacy method, this article estimates the possible minimum central pressure of TCs affecting southern Fujian where a nuclear power will be located. Results show that the observed minimum central pressure of TCs agrees well with the results determined with the methods above and there is little difference between them (the minimum central pressure is 867.4 hPa and 868.1 hPa, respectively, in a 1,000-yr return period). Established with the theory of atmospheric dynamics, the determinacy method yields a result of 867.28 hPa/1000 years, only a little smaller than the result of the probability method. Because of randomicity in parameter adjustment with the Pearson-Ⅲ method whereas the determinacy method is theoretically solid and its estimates are the smallest of the three methods, it is therefore reasonable, for security and conservative concerns, to adopt the result determined with the determinacy method as the possible maximum intensity of TC (with the central pressure being 867.28 hPa in a 1,000-yr return period).     

A Comparison of Two Bulk Microphysics Parameterizations for the Study of Aerosol Impacts on an Idealized Supercell

Idealized supercell storms are simulated with two aerosol-aware bulk microphysics schemes(BMSs),the Thompson and the Chen-Liu-Reisner(CLR),using the Weather Research and Forecast(WRF)model.The objective of this study is to investigate the parameterizations of aerosol effects on cloud and precipitation characteristics and assess the necessity of introducing aerosols into a weather prediction model at fine grid resolution.The results show that aerosols play a decisive role in the composition of clouds in terms of the mixing ratios and number concentrations of liquid and ice hydrometeors in an intense supercell storm.The storm consists of a large amount of cloud water and snow in the polluted environment,but a large amount of rainwater and graupel instead in the clean environment.The total precipitation and rain intensity are suppressed in the CLR scheme more than in the Thompson scheme in the first three hours of storm simulations.The critical processes explaining the differences are the auto-conversion rate in the warm-rain process at the beginning of storm intensification and the low-level cooling induced by large ice hydrometeors.The cloud condensation nuclei(CCN)activation and auto-conversion processes of the two schemes exhibit considerable differences,indicating the inherent uncertainty of the parameterized aerosol effects among different BMSs.Beyond the aerosol effects,the fall speed characteristics of graupel in the two schemes play an important role in the storm dynamics and precipitation via low-level cooling.The rapid intensification of storms simulated with the Thompson scheme is attributed to the production of hail-like graupel.     

THE IMPACTS OF MADDEN-JULIAN OSCILLATION ON SPRING RAINFALL IN EAST CHINA

Phase composite analyses are conducted to investigate the possible effect of the Madden–Julian oscillation(MJO)on the spring rainfall anomalies in East China by using the Real-time Multivariate MJO(RMM)index from Australian Meteorological Bureau.The results show that the rainfall anomalies over the mid-and lower-valley of Yangtze River are positive when the MJO shifts eastward to the mid-and eastern-Indian Ocean,and anomalous precipitation over South China are positive when the MJO moves further eastward to the maritime continent,whereas spring rainfall anomalies over East China are negative in the other MJO episodes.The MJO impacts on the precipitation over East China result from the changes in large-scale atmospheric circulation as well as vorticity and water vapor transportation in the mid-and lower-troposphere.     

Hydro-climatic Characteristics of Yarlung Zangbo River Basin since the Last Glacial Maximum

Global climate changes significantly impact the water condition of big rivers in glacierized high mountains. However,there is a lack of studies on hydrological changes within river basins caused by climate changes over a geological timescale due to the impossibility of direct observations. In this study, we examine the hydro-climatic variation of the Yarlung Zangbo River Basin in the Tibet Plateau since the Last Glacial Maximum(LGM) by combining δ18 O proxy records in Indian and Omani caves with the simulated Indian summer monsoon, surface temperature, precipitation, evapotranspiration and runoff via the Community Climate System Model and the reconstructed glacier coverage via the Parallel Ice Sheet Model. The mean river runoff was kept at a low level of 145 billion cubic meters per year until an abrupt increase at a rate of 8.7 million cubic meters per year in the B?lling-Aller?d interval(BA). The annual runoff reached a maximum of 250 billion cubic meters in the early Holocene and then reduced to the current value of 180 billion cubic meters at a rate of 6.4 million cubic meters per year. The low runoff in the LGM and Heinrich Stadial 1(HS1) is likely attributed to such a small contribution of precipitation to runoff and the large glacier cover. The percentage of precipitation to runoff was only 20%during the LGM and HS1. Comparison of glacier area among different periods indicates that the fastest deglaciation occurred during the late HS1, when nearly 60% of glacier area disappeared in the middle reach, 50% in the upper reach,and 30% in the lower reach. The rapid deglaciation and increasing runoff between the late HS1 and BA may have accelerated widespread ice-dam breaches and led to extreme outburst flood events. Combining local geological proxy records and regional simulations could be a useful approach for the study of paleo-hydrologic variations in big river basins.     

Verification of Subseasonal-to-Seasonal Forecasts for Major Stratospheric Sudden Warmings in Northern Winter from 1998/99 to 2012/13

This study reports verification results of hindcast data of four systems in the subseasonal-to-seasonal(S2 S) prediction project for major stratospheric sudden warmings(MSSWs) in northern winter from 1998/99 to 2012/13. This report deals with average features across all MSSWs, and possible differences between two MSSW types(vortex displacement and split types). Results for the average features show that stratospheric forecast verifications, when further averaged among the four systems, are judge...     

南京三千公尺高空之风向与天气之预测

晚近日本籐原笑平(Fujiwhora)博士于地球物理杂志发表「根据三千公尺高空等压线,以预测天气之一例证」一文,谓日本最近用三千公尺高空之等压线,作每日天气之预测,已得相当成就。氏之经验法则谓自九月以迄五月,日本太平洋沿岸,三千公尺高空之等压线,来自西南者,可形去致雨,而来自西北者,则可期晴明。此种倾向颇为显著。     

The Distribution and Uncertainty Quantification of Wind Profile in the Stochastic General Ekman Momentum Approximation Model

The general Ekman momentum approximation boundary-layer model(GEM) can be effectively used to describe the physical processes of the boundary layer. However, eddy viscosity, which is an approximated value, can lead to uncertainty in the solutions. In this paper, stochastic eddy viscosity is taken into consideration in the GEM, and generalized polynomial chaos is used to quantify the uncertainty. The goal of uncertainty quantification is to investigate the effects of uncertainty in the eddy viscosity on the model and to subsequently provide reliable distribution of simulation results. The performances of the stochastic eddy viscosity and generalized polynomial chaos method are validated based on three different types of eddy viscosities, and the results are compared based on the Monte Carlo method. The results indicate that the generalized polynomial chaos method can be accurately and efficiently used in uncertainty quantification for the GEM with stochastic eddy viscosity.