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1.
臭氧(O3)是大气微量成分之一。近地层O3含量的增加,将直接影响农作物的生长发育。本文简要介绍了国外有关O3对农作物影响的研究方法和试验研究结果,以及我国有关O3对农作物影响的研究动态。 相似文献
2.
在试验研究的基础上,文中尝试利用数值模拟方法评估O3和CO2浓度变化对作物的影响.以农田生态系统碳氮生物化学模型(DNDC)为基础,对其中的作物子模型进行改进,加入O3对冬小麦光合作用和叶片生长影响的模拟,结合原模型中有关CO2对冬小麦光合作用影响的模拟,建立反映O3和CO2浓度变化对冬小麦生长发育和产量形成影响的作物模型.文章对DNDC模型进行了参数修正以适用于中国华北地区;文章参考前人的工作,引用了两种O3对作物光合作用影响的模拟方法进行比较,分别是O3对初始光利用率的影响和O3对叶片光合作用的直接影响;在此基础上,进一步考虑O3对冬小麦叶片生长的影响,根据试验资料,建立了O3对叶片生长影响系数. 相似文献
3.
近地层O3和CO2浓度变化对冬小麦影响的数值模拟:Ⅱ模拟结果和分析 总被引:4,自引:2,他引:4
针对CO2和O3浓度变化对冬小麦影响,改进了农田生态系统碳氮生物化学模型(DNDC),并利用模型模拟了O3和CO2浓度变化对冬小麦生长发育和产量的影响,检验了模型的模拟效果.通过对原DNDC模型适用性的调整,使之适用于固城站,为进一步改进作物模型打下了可靠的基础.通过试验资料验证表明,模型较好地反映了O3和CO2浓度变化对冬小麦生长发育和产量形成的影响.通过敏感性分析得出,模型对温度变化反映灵敏;在CO2浓度倍增情况下,O3浓度变化对冬小麦的复合影响分析看出,一定浓度范围内,CO2可缓解O3对作物影响的负效应,O3对CO2带来的正效应有削弱作用. 相似文献
4.
区域化学输送模式中NO x和O3源示踪法的引入 总被引:4,自引:0,他引:4
发展了化学输送模式中氮氧化合物(NOx)和臭氧(O3)的一种源示踪方法,对这种示踪法及其应用模式作了详细介绍,并结合臭氧光化学反应机理的分析描述了NOx和O3示踪物浓度方程的推导过程。将这种示踪法引用到区域化学输送模式中,并以太原和石家庄地表NOx人为排放产生的活性氮化物和臭氧为例,演示了污染物向北京的输送过程,模拟的O3,NOx和NOz示踪物浓度时空分布与O3,NOx和NOz在大气中的衰减尺度分析一致,表明该示踪法是一种有效的研究区域氮氧化物以及臭氧来源和输送转化过程的方法。个例模拟分析结果显示:太原和石家庄的地表人为排放产生的NOx本身并不能输送到北京,但通过它们产生的O3和HNO3可以输送到北京,对北京地表附近大气污染造成影响。 相似文献
5.
中层大气行星波在臭氧的季节和年际变化中输运作用的数值研究 I. 常定流的情况 总被引:1,自引:3,他引:1
本文构造了一个34层球坐标原始方程波-流相互耦合谱模式,利用此模式从拉格朗日平均环流的观点研究了在常定流下行星波对臭氧的输运作用。研究结果表明,行星波对臭氧的输运有明显的季节变化,在北半球冬季,由于行星波上传到平流层而大大增强了中高纬地区向极地向下的O3输运;并且还表明,热带纬向风的QBO不仅通过影响东、西风切变而引起热带O3分布的年际变化,而且通过影响行星波的传播引起了行星波对O3输运的年际变化,这表现为当热带纬向风处于东风位相时,中高纬地区行星波对O3的输运比西风位相时强 相似文献
6.
7.
近地层大气臭氧对作物光合作用影响的数值模拟研究 总被引:6,自引:0,他引:6
近地层O3浓度增加对作物光合产生不利影响,因此,利用TE-49C型臭氧自动观测仪对常熟农田上方O3浓度进行了逐时测定,同时利用OTC-1型农田开顶式气室,测定了不同O3浓度对冬小麦叶片光合作用的影响.在此基础上,首次建立了O3对冬小麦光合作用影响的数值机理模式,模式分辨率达到瞬时时间尺度,空间积分采用Ross方案,具有较高分辨率和准确度.对O3浓度观测表明:O3浓度逐时值变化在0~160×10-9之间,相比之下日平均值变化较小,仅在5×10-9~60×10-9之内;长江中下游地区农田上方O3存在三种典型日变化形式:高浓度单峰型、高浓度多峰型和低浓度平缓型.数值分析表明:全晴天状况下高浓度单峰型对光合作用日总量影响最大.数值敏感分析表明:O3浓度和辐射同步变化时,随着日总辐射量的加大,臭氧浓度增加对光合作用的影响程度逐渐加强.全生育期积分表明:水肥适宜时,由于O3影响冬小麦光合总损失量约为9.22%. 相似文献
8.
在不同领域和不同研究目的中,大气臭氧会用数密度、体积混合比、质量浓度和柱量等不同物理量表示。由于这些不同量纲的臭氧量的同时存在,对大气臭氧的使用和相互比较造成混乱和不便。基于气体状态方程,推导了大气臭氧不同量纲之间的转换关系,并提出了臭氧数密度廓线与臭氧柱量廓线的相互转换模型。实际应用表明,IUP(Institute of Environmental Physics)气象库提供的数密度和体积混合比转换差异在10%以内,转换精度受温度和气压影响。以激光雷达臭氧数据验证SBUS(Solar Backscatter Ultraviolet Sounder)臭氧数据时发现,最大偏差达20%,且第8、9、11层具有较高的一致性。利用UGAMP(UK Universities Global Atmospheric Modelling Programme)库中臭氧数据与SCIA-O3 (SCIAMACHY O3) 产品比较发现,15-45km之间平均偏差在10%以内。 相似文献
9.
基于2014-2017年西安市环保局臭氧观测资料、泾河气象站总辐射和气象资料以及长安气象站紫外辐射和气象资料,对西安市臭氧污染特征及其与气象条件的关系进行了研究。结果表明:西安市臭氧质量浓度的日变化和月变化均呈明显的单峰形态;日最小值22.2μg/m^3和最大值100.7μg/m^3分别出现在07时和16时;臭氧日最大8 h平均质量浓度(用C8h(O3)表示)月均值最大为148.5μg/m^3,最小为30.0μg/m^3,分别出现在7月和11月。总辐射日最大辐照度、日总辐射曝辐量和日紫外辐射曝辐量与C8h(O3)之间具有显著的正相关关系,并且以日紫外辐射曝辐量与C8h(O3)的相关性最高,表明紫外辐射对近地面臭氧质量浓度的影响更为强烈。日最高气温、平均气温、日照时数和C8h(O3)正相关,风速、相对湿度与C8h(O3)负相关,表明晴空时高温、低湿、小风更有利于近地面臭氧的形成。统计关系显示,在5-8月,当日最高气温大于35℃或日最低相对湿度小于40%时,需要警惕臭氧超标污染的发生。 相似文献
10.
近地面臭氧研究进展 总被引:11,自引:0,他引:11
近地面臭氧是空气中氮氧化物和挥发性有机物发生光化学反应的产物,其浓度与气象条件密切相关。晴天少云、紫外辐射较强、温度较高、相对湿度较低以及风速较小的天气,均有利于臭氧的生成,其中紫外辐射是产生臭氧最关键的因素。臭氧前体物(氮氧化物和挥发性有机物)的浓度及其比值是影响近地面臭氧浓度的另外三个重要因素。我国大多数城市的O3处于VOC控制区,即NOx浓度的增加会引起O3浓度的降低,而VOCs浓度的增加则会使其浓度升高。因而VOC源解析问题成为近年来O3研究的一个热点问题。同时,由于气溶胶可以直接吸收、散射太阳紫外辐射、短波辐射以及大气长波辐射,因此气溶胶的存在会影响大气中光化学反应的进程,从而影响臭氧的光化学生成,气溶胶对近地面臭氧的影响已成为目前大气环境的前沿课题。 相似文献
11.
Numerical Simulation Study on the Impacts of Tropospheric O3 and CO2 Concentration Changes on Winter Wheat.Part I: Model Description 
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下载免费PDF全文 Ozone is well documented as the air pollutant most damaging to agricultural crops and other plants.It is reported that tropospheric O3 concentration increases rapidly in recent 20 years. Evaluating and predicting impacts of ozone concentration changes on crops are drawing great attention in the scientific community. In China, main study method about this filed is controlled experiments, for example, Open Top Chambers. But numerical simulation study about impacts of ozone on crops with crop model was developed slowly, what is more, the study about combined impacts of ozone and carbon dioxide has not been reported.The improved agroecosystem model is presented to evaluate simultaneously impacts of tropospheric O3 and CO2 concentration changes on crops in the paper by integrating algorithms about impacts of ozone on photosynthesis with an existing agroecosystem biogeochemical model (named as DNDC). The main
physiological processes of crop growth (phenology, leaf area index, photosynthesis, respiration, assimilated allocation and so on) in the former DNDC are kept. The algorithms about impacts of ozone on photosynthesis and winter wheat leaf are added in the modified DNDC model in order to reveal impacts of ozone and carbon dioxide on growth, development, and yield formation of winter wheat by coupling the simulation about impacts of carbon dioxide on photosynthesis of winter wheat which exists in the former DNDC. In
the paper, firstly assimilate allocation algorithms and some genetic parameters (such as daily thermal time of every development stage) were modified in order that DNDC can be applicable in North China. Secondly impacts of ozone on crops were simulated with two different methods-one was impacts of ozone on light use efficiency , and the other was direct effects of ozone on leaves photosynthesis. The latter simulated results are closer to experiment measurements through comparing their simulating results. At last the method of direct impacts of ozone on leaf growth is adopted and the coe cients about impacts of ozone on leaf growth
and death are ascertained. Effects of climate changes, increasing ozone, and carbon dioxide concentration on agroecosystem are tried to be simulated numerically in the study which is considered to be advanced and credible. 相似文献
12.
Numerical Simulation Study on the Impacts of Tropospheric and CO_2 Concentration Changes on Winter Wheat. Part I: Model Description 下载免费PDF全文
下载免费PDF全文 Ozone is well documented as the air pollutant most damaging to agricultural crops and other plants. It is reported that tropospheric O3 concentration increases rapidly in recent 20 years. Evaluating and predicting impacts of ozone concentration changes on crops are drawing great attention in the scientific community. In China, main study method about this filed is controlled experiments, for example, Open Top Chambers. But numerical simulation study about impacts of ozone on crops with crop model was developed slowly, what is more, the study about combined impacts of ozone and carbon dioxide has not been reported. The improved agroecosystem model is presented to evaluate simultaneously impacts of tropospheric O3 and CO2 concentration changes on crops in the paper by integrating algorithms about impacts of ozone on photosynthesis with an existing agroecosystem biogeochemical model (named as DNDC). The main physiological processes of crop growth (phenology, leaf area index, photosynthesis, respiration, assimilated allocation and so on) in the former DNDC are kept. The algorithms about impacts of ozone on photosynthesis and winter wheat leaf are added in the modified DNDC model in order to reveal impacts of ozone and carbon dioxide on growth, development, and yield formation of winter wheat by coupling the simulation about impacts of carbon dioxide on photosynthesis of winter wheat which exists in the former DNDC. In the paper, firstly assimilate allocation algorithms and some genetic parameters (such as daily thermal time of every development stage) were modified in order that DNDC can be applicable in North China. Secondly impacts of ozone on crops were simulated with two different methods- one was impacts of ozone on light use efficiency, and the other was direct effects of ozone on leaves photosynthesis. The latter simulated results are closer to experiment measurements through comparing their simulating results. At last the method of direct impacts of ozone on leaf growth is adopted and the coefficients about impacts of ozone on leaf growth and death are ascertained. Effects of climate changes, increasing ozone, and carbon dioxide concentration on agroecosystem are tried to be simulated numerically in the study which is considered to be advanced and credible. 相似文献
13.
Numerical Simulation Study on the Impacts of Tropospheric O3 and CO2 Concentration Changes on Winter Wheat. Part II: Simulation Results and Analyses 下载免费PDF全文
下载免费PDF全文 With the rapid development of industrialization and urbanization, the enrichment of tropospheric ozone and carbon dioxide concentration at striking rates has caused effects on biosphere, especially on crops. It is generally accepted that the increase of CO2 concentration will have obverse effects on plant productivity while ozone is reported as the air pollutant most damaging to agricultural crops and other plants. The Model of Carbon and Nitrogen Biogeochemistry in Agroecosystems (DNDC) was adapted to evaluate simultaneously impacts of climate change on winter wheat. Growth development and yield formation of winter wheat
under different O3 and CO2 concentration conditions are simulated with the improved DNDC model whose structure has been described in another paper. Through adjusting the DNDC model applicability, winter wheat growth and development in Gucheng Station were simulated well in 1993 and 1999, which is in favor of modifying the model further. The model was validated against experiment observation, including development stage data, leaf area index, each organ biomass, and total aboveground biomass. Sensitivity tests demonstrated that the simulated results in development stage and biomass were sensitive to temperature change. The main conclusions of the paper are the following: 1) The growth and yield of winter wheat under CO2 concentration of 500 ppmv, 700 ppmv and the current ozone concentration are simulated respectively by the model. The results are well fitted with the observed data of OTCs experiments. The results show that increase of CO2 concentration may improve the growth of winter wheat and elevate the yield. 2) The growth and yield of winter wheat under O3 concentration of 50 ppbv, 100 ppbv, 200 ppbv and the based concentration CO2 are simulated respectively by the model. The simulated curves of stem, leaf, and spike organs growth as well as leaf area index are well accounted with the observed data. The results reveal that ozone has negative e ects on the growth and yield of winter wheat. Ozone accelerates the process of leaf senescence and causes yield loss. Under very high ozone concentration, crops are damaged dramatically and even dead. 3) At last, by the model possible effects of air temperature change and combined effects of O3 and CO2 are estimated respectively. The results show that doubled CO2 concentration may alleviate negative effect of O3 on biomass and yield of winter wheat when ozone concentration is about 70-80 ppbv. The obverse effects of CO2 are less than the adverse effects of O3 when the concentration of ozone is up to 100 ppbv. Future work should determine whether it can be applied to other species by adjusting the values of related parameters, and whether the model can be adapted to predict ozone e ects on crops in farmland environment. 相似文献
14.
Numerical Simulation Study on the Impacts of Tropospheric O_3 and CO_2 Concentration Changes on Winter Wheat. Part Ⅱ: Simulation Results and Analyses 下载免费PDF全文
下载免费PDF全文 With the rapid development of industrialization and urbanization, the enrichment of tropospheric ozone and carbon dioxide concentration at striking rates has caused effects on biosphere, especially on crops. It is generally accepted that the increase of CO2 concentration will have obverse effects on plant productivity while ozone is reported as the air pollutant most damaging to agricultural crops and other plants. The Model of Carbon and Nitrogen Biogeochemistry in Agroecosystems (DNDC) was adapted to evaluate simultaneously impacts of climate change on winter wheat. Growth development and yield formation of winter wheat under different O3 and CO2 concentration conditions are simulated with the improved DNDC model whose structure has been described in another paper. Through adjusting the DNDC model applicability, winter wheat growth and development in Gucheng Station were simulated well in 1993 and 1999, which is in favor of modifying the model further. The model was validated against experiment observation, including development stage data, leaf area index, each organ biomass, and total aboveground biomass. Sensitivity tests demonstrated that the simulated results in development stage and biomass were sensitive to temperature change. The main conclusions of the paper are the following: 1) The growth and yield of winter wheat under CO2 concentration of 500 ppmv, 700 ppmv and the current ozone concentration are simulated respectively by the model. The results are well fitted with the observed data of OTCs experiments. The results show that increase of CO2 concentration may improve the growth of winter wheat and elevate the yield. 2) The growth and yield of winter wheat under O3 concentration of 50 ppbv, 100 ppbv, 200 ppbv and the based concentration CO2 are simulated respectively by the model. The simulated curves of stem, leaf, and spike organs growth as well as leaf area index are well accounted with the observed data. The results reveal that ozone has negative effects on the growth and yield of winter wheat. Ozone accelerates the process of leaf senescence and causes yield loss. Under very high ozone concentration, crops are damaged dramatically and even dead. 3) At last, by the model possible effects of air temperature change and combined effects of O3 and CO2 are estimated respectively. The results show that doubled CO2 concentration may alleviate negative effect of O3 on biomass and yield of winter wheat when ozone concentration is about 70-80 ppbv. The obverse effects of CO2 are less than the adverse effects of O3 when the concentration of ozone is up to 100 ppbv. Future work should determine whether it can be applied to other species by adjusting the values of related parameters, and whether the model can be adapted to predict ozone effects on crops in farmland environment. 相似文献
15.
霾和光化学污染已成为我国最严重的环境气象灾害,受到政府和公众广泛关注。针对我国的环境气象问题,国内外科研人员开展了大量研究工作,发表了一系列的研究成果。该文对近年来我国霾和光化学污染的观测、分析和影响研究方面的文献进行综述,为将来相关研究提供基础。在霾污染方面,主要回顾了霾的现象与判别、组成与来源、影响霾的气象因素、霾的长期趋势等方面的研究进展。在光化学污染方面,主要回顾了污染的特征与水平、污染的区域化、臭氧垂直分布、地面臭氧影响因素、臭氧污染发展趋势等方面的研究进展。此外,还概括了霾和光化学污染危害研究主要成果,在文献综述的基础上,提出了未来研究中值得关注的几方面问题,包括进一步加强霾和雾的科学判识方法、污染物相互作用、污染-气象-化学-生态间耦合效应研究,特别关注光化学污染发展态势,加强长期观测资料的积累、分析与应用等。 相似文献
16.
Lee Hannah Camila I. Donatti Celia A. Harvey Eric Alfaro Daniel Andres Rodriguez Claudia Bouroncle Edwin Castellanos Freddy Diaz Emily Fung Hugo G. Hidalgo Pablo Imbach Peter Läderach Jason P. Landrum Ana Lucía Solano 《Climatic change》2017,141(1):29-45
Climate change will have serious repercussions for agriculture, ecosystems, and farmer livelihoods in Central America. Smallholder farmers are particularly vulnerable due to their reliance on agriculture and ecosystem services for their livelihoods. There is an urgent need to develop national and local adaptation responses to reduce these impacts, yet evidence from historical climate change is fragmentary. Modeling efforts help bridge this gap. Here, we review the past decade of research on agricultural and ecological climate change impact models for Central America. The results of this review provide insights into the expected impacts of climate change and suggest policy actions that can help minimize these impacts. Modeling indicates future climate-driven changes, often declines, in suitability for Central American crops. Declines in suitability for coffee, a central crop in the regional economy, are noteworthy. Ecosystem models suggest that climate-driven changes are likely at low- and high-elevation montane forest transitions. Modeling of vulnerability suggests that smallholders in many parts of the region have one or more vulnerability factors that put them at risk. Initial adaptation policies can be guided by these existing modeling results. At the same time, improved modeling is being developed that will allow policy action specifically targeted to vulnerable groups, crops, and locations. We suggest that more robust modeling of ecological responses to climate change, improved representation of the region in climate models, and simulation of climate influences on crop yields and diseases (especially coffee leaf rust) are key priorities for future research. 相似文献
17.
Paula L. M. Gonzalez Lorenzo M. Polvani Richard Seager Gustavo J. P. Correa 《Climate Dynamics》2014,42(7-8):1775-1792
On a hemispheric scale, it is now well established that stratospheric ozone depletion has been the principal driver of externally forced atmospheric circulation changes south of the Equator in the last decades of the 20th Century. The impact of ozone depletion has been felt over the entire hemisphere, as reflected in the poleward drift of the midlatitude jet, the southward expansion of the summertime Hadley cell and accompanying precipitation trends deep into the subtropics. On a regional scale, however, surface impacts directly attributable to ozone depletion have yet to be identified. In this paper we focus on South Eastern South America (SESA), a region that has exhibited one of the largest wetting trends during the 20th Century. We study the impact of ozone depletion on SESA precipitation using output from 6 different climate models, spanning a wide range of complexity. In all cases we contrast pairs of model integrations with and without ozone depletion, but with all other forcings identically specified. This allows for unambiguous attribution of the computed precipitation trends. All 6 climate models consistently reveal that stratospheric ozone depletion results in a significant wetting of SESA over the period 1960–1999. Taken as a whole, these model results strongly suggest that the impact of ozone depletion on SESA precipitation has been as large as, and quite possibly larger than, the one caused by increasing greenhouse gases over the same period. 相似文献
18.
A global two-dimensional (altitude-latitude) chemistry transport model is used to follow the changes in the tropospheric distribution of the two major radiatively active trace gases, methane and ozone, following step changes to the sustained emissions of the short-lived trace gases methane, carbon monoxide and non-methane hydrocarbons. The radiative impacts were dependent on the latitude chosen for the applied change in emissions. Step change global warming potentials (GWPs) were derived for a range of short-lived trace gases to describe their time-integrated radiative forcing impacts for unit emissions relative to that of carbon dioxide. The GWPs show that the tropospheric chemistry of the hydrocarbons can produce significant indirect radiative impacts through changing the tropospheric distributions of hydroxyl radicals, methane and ozone. For aircraft, the indirect radiative forcing impact of the NO
x
emissions appears to be greater than that from their carbon dioxide emissions. Quantitative results from this two-dimensional model study must, however, be viewed against the known inadequacies of zonally-averaged models and their poor representation of many important tropospheric processes. 相似文献
19.
Andrew Challinor Tim Wheeler Chris Garforth Peter Craufurd Amir Kassam 《Climatic change》2007,83(3):381-399
Africa is thought to be the region most vulnerable to the impacts of climate variability and change. Agriculture plays a dominant
role in supporting rural livelihoods and economic growth over most of Africa. Three aspects of the vulnerability of food crop
systems to climate change in Africa are discussed: the assessment of the sensitivity of crops to variability in climate, the
adaptive capacity of farmers, and the role of institutions in adapting to climate change. The magnitude of projected impacts
of climate change on food crops in Africa varies widely among different studies. These differences arise from the variety
of climate and crop models used, and the different techniques used to match the scale of climate model output to that needed
by crop models. Most studies show a negative impact of climate change on crop productivity in Africa. Farmers have proved
highly adaptable in the past to short- and long-term variations in climate and in their environment. Key to the ability of
farmers to adapt to climate variability and change will be access to relevant knowledge and information. It is important that
governments put in place institutional and macro-economic conditions that support and facilitate adaptation and resilience
to climate change at local, national and transnational level. 相似文献
20.
平流层对对流层的作用是准确评估、预测对流层气候变化的一个重要方面。其中平流层成分尤其是臭氧的变化,可以改变平流层乃至对流层的辐射平衡,从而影响平流层、对流层的热动力过程。本文从辐射、动力2个角度介绍了平流层臭氧影响对流层气候变化的若干研究进展。平流层臭氧可以通过长短波辐射的方式对对流层大气造成辐射强迫,利用大气化学气候模式可以定量计算平流层臭氧变化引起的辐射强迫,但是辐射强迫的估算受模式中辐射传输模块本身缺陷的影响存在不确定性。动力方面,平流层臭氧变化产生的辐射效应可以改变温度的垂直和经向梯度,造成波折射指数的变化,进而影响平流层甚至对流层内波的折射与反射,通过上对流层下平流层区域内的波—流相互作用,对对流层气候产生影响。另外,南极臭氧损耗可通过大气环状模影响冬春季中高纬度对流层的天气气候,但是其影响的强度大小以及物理机制仍需进一步的确认。值得注意的是,北极平流层臭氧的变化与北半球中高纬度气候变化之间的关系相比南半球要更加复杂,需要更为深入的研究。 相似文献