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大气中O3和CO2增加对大豆复合影响的试验研究 总被引:1,自引:0,他引:1
利用OTC-1型开顶式气室,对大豆"中黄14"进行了长时期不同O3和CO2处理的接触试验,模拟研究CO2和O3浓度倍增及其交互作用对大豆发育期、黄叶率和绿叶率、根瘤、生物量及其分配、产量结构、籽粒品质及叶片膜保护系统的影响,结果表明:单独O3浓度倍增,发育期明显提前;生物量最多可减少近一半,产量最多减产60%以上;粗蛋白含量增加6.2%,粗脂肪含量降低7.6%;叶片脂膜过氧化加剧.单独CO2浓度倍增,开花后发育期有所延迟;对生物量及产量有明显的正效应,成熟时总生物量和籽粒产量分别比T5增加21.0%和20.3%;粗蛋白和粗脂肪含量分别下降3.3%和1.6%;结荚前叶片脂膜过氧化反应减轻.CO2和O3持续倍增和逐渐达到倍增交互作用处理,在生物量、产量方面表现为CO2的影响大于O3,在叶片膜保护系统方面表现为O3的影响大于CO2,粗蛋白含量下降,粗脂肪含量上升,叶片脂质过氧化加剧.熏气处理均可造成:黄叶率上升,绿叶率下降,凋落物增加,且单独O3浓度倍增的处理最明显,通气仅10天黄叶率就高于50%;超氧化物歧化酶活性增强;气孔阻力增加,蒸腾速率下降,且单独CO2浓度倍增的处理最明显,尤其在高湿阴天,气孔阻力和蒸腾速率变化最高分别可达增加234.0%和下降58.5%. 相似文献
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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.
小麦发育期对冬季积温变化的响应分析 总被引:3,自引:0,他引:3
利用沁阳站1980-2007年冬季积温和小麦发育期资料,分析了冬季积温和小麦发育期的变化规律,用相关分析和典型年份对比方法探讨了冬季积温对小麦发育期的影响.结果表明:1980-2007年冬季积温增加率为6.8(℃·d)/a,1995年以后小麦发育期基本持续提前;冬季积温与冬小麦各发育期呈负相关,最显著的是起身期,其次是抽穗、开花、返青期;冬季积温典型偏高年份作物平均发育期比典型偏低年份的早,最明显的是起身期,提前了26 d,其次是返青期为21 d,再次是全生育期为16 d. 相似文献
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CO2和O3浓度倍增对作物影响的研究进展 总被引:14,自引:0,他引:14
文中利用自行设计的OTC - 1型开顶式气室进行了 9a的田间试验 ,取得了一批质量可靠的试验数据 ,分析了CO2 浓度倍增对大豆、冬小麦、棉花、玉米、春小麦和谷子的生物量、产量及品质的影响 ,结果表明CO2 浓度倍增对上述 6种作物的生物量及产量的影响均是正效应 ,对冬小麦、棉花和谷子品质的影响可能是有利的 ,对玉米品质的影响可能是不利的 ,对大豆的影响不大 ;分析了O3 浓度倍增对冬小麦、水稻、油菜和菠菜生物量、产量及品质的影响 ,结果表明O3 浓度倍增对上述 4种作物生物量的影响均是负效应 ,对冬小麦和水稻的产量影响是负效应 ,但是冬小麦和水稻籽粒中粗蛋白和 17种氨基酸含量都有所增加 ;分析了CO2 和O3 浓度复合倍增对大豆生物量、产量及品质的影响 ,结果是生物量和产量呈增加趋势 ,说明了CO2 的正效应大于O3 的负效应。采用作物模型数值模拟方法 ,分析了CO2 和O3 浓度倍增对冬小麦生物量及产量的影响。 相似文献
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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
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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
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1 资料来源1 999~ 2 0 0 1年 ,在西峰农试站试验地对冬小麦、玉米、马铃薯 3种作物的不同发育期用 1∶1 0 0 0浓度的 2 0 0 3溶液进行喷施对比观测 ,取得了作物产量分析资料。2 资料分析2 .1 冬小麦资料分析2 0 0 0、2 0 0 1年连续两年对露地冬小麦西峰 2 0号在苗期、拔节、抽穗期进行不同处理喷施 ,分析结果见表 1、表 2。发现几种处理均有增产效果 ,最显著的是拔节期 ,不论是在拔节期喷一次 ,还是在苗期、拔节各喷一次及苗期、拔节、抽穗期各喷一次 ,均有显著的增产效果 ;其次是抽穗期 ,而苗表 1 1999~ 2 0 0 0年冬小麦不同处理产… 相似文献
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甘肃黄土高原地温与冬小麦发育期的关系分析 总被引:8,自引:0,他引:8
用黄土高原代表站甘肃省庆阳西峰站1971~2005年5、10、15、20 cm地温和1981~2005年冬小麦发育期资料,分析了地温的时间变化规律及对冬小麦发育期的影响.结果表明,西峰10 cm地温除夏季外,其余季节呈持续升高的趋势.地温与冬小麦发育期成负相关,与冬季地温相关最显著的是乳熟期,相关系数为-0.57~-0.65,与春季地温相关最显著的是返青期,相关系数为-0.60~-0.63.冬季典型年份各平均发育期差异最显著的是冬小麦的起身期提前了15 d,春季典型年份最显著的是冬小麦的全生育期提前了23 d. 相似文献
10.
冬小麦干旱综合防御集成技术推广试验研究 总被引:1,自引:0,他引:1
冬小麦底墒效应+土壤深松保墒增产效应+玉米千秆覆盖效应(分覆盖,粉碎还田处理)+有限水分胁迫高产效应集成技术的推广试验研究结果表明,覆盖处理,粉碎还田处理的冬小麦发育期的根,茎,叶,穗,总生物量与对照相比有明显增加,其中粉碎还田处理的增加量明显大于覆盖处理,666.67m^2的产量分别比对照增加19.7%,35.6%,全生育期耗水量分别比对照减少14.8%,12.1%,节约灌溉1-2水。 相似文献
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Numerical Simulation Study on the Impacts of Tropospheric O_3 and CO_2 Concentration Changes on Winter Wheat. Part Ⅱ: Simulation Results and Analyses 
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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
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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
13.
O. A. Syrovatkina I. L. Karol A. M. Shalamyanskii L. P. Klyagina 《Russian Meteorology and Hydrology》2008,33(2):91-97
Synoptic analysis of monthly and daily mean total ozone fields is carried out using ground-based (Roshydromet) and TOMS measurements. Large interannual changes in the evolution of the stratospheric polar vortex and the North Pacific anticyclone influence the formation and dynamics of the winter-spring ozone fields in the stratosphere of high northern latitudes. The analysis shows considerable variations in the direction of zonal ozone transport from the sector of ozone inflow from low latitudes and accumulation in the Far East depending on the winter polar stratosphere temperature and the quasi-biennial oscillation (QBO) phase. In years with the easterly QBO phase and the warm polar stratosphere, ozone at the end of winter is transported to northeastern Canada and Atlantic. In years with the easterly phase and cold polar stratosphere, ozone transport is directed to northern Eurasia. These characteristics will be verified on extensive observational data. 相似文献
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Numerical Simulation Study on the Impacts of Tropospheric O3 and CO2 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 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
15.
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
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The harmonic analyses of monthly mean total ozone in the atmosphere over the Northern Hemisphere for 26 years (1960-1985) are made by using the Fourier expansion. The analysed results show that there is obviously a quasi-biennial oscillation (QBO) in the interannual variations of the amplitudes of total ozone. Generally, the amplitudes of wavenumber 1 and 2 during the westerly of the equatorial QBO are larger than those during the easter-ly. In the early winter, the amplitude of wavenumber 1 during the easterly phase is larger, and in the late winter, it is larger during the westerly phase. These are in good agreement with the observational distributions. 相似文献
17.
水分胁迫对华北平原冬小麦地上部分及产量的影响 总被引:1,自引:0,他引:1
以“济麦-22”为供试品种,利用中国气象局固城生态环境与农业气象试验站大型根系观测系统,研究冬小麦在重度干旱胁迫(≤40.0%)、轻中度干旱胁迫(40.1%-55.0%)和适宜(55.1%-80.0%)3种水分胁迫条件下地上部分对水分胁迫的响应,以探索水分胁迫对华北平原冬小麦产量的影响,分析不同水分胁迫对冬小麦产量的影响程度。结果表明:华北平原冬小麦在轻中度干旱胁迫和重度干旱胁迫下,小麦全生育期的天数缩短,株高、叶面积及灌浆速率均呈不同程度的减少。3种水分胁迫的株高增长量为适宜>轻中度胁迫>重度胁迫,灌浆速率为适宜>轻中度胁迫>重度胁迫。土壤水分胁迫引起冬小麦物质分配更多地向支持生长的茎秆转移,在生长发育过程中受到水分胁迫,小麦产量将降低,重度胁迫条件下小麦产量为适宜水分条件的69%。 相似文献
18.
为探讨北方冬麦区节水灌溉的关键时期,借助干旱和灌溉对冬小麦冠层光分布,获取本地化参数,为华北农业干旱预报模型的修正提供依据。采用美国CID公司生产的CI-110型植物冠层分析仪,对干旱和灌溉条件下冬小麦冠层内光分布进行直接测定。结果表明,干旱和灌溉条件下,无论是高氮还是低氮、中氮,平均叶面倾角(MLA)都随生育期的延长呈现出先下降再上升的趋势。高氮和低氮时,随着生育期的延长,干旱处理和灌溉处理的冬小麦散射辐射透过系数(TCDP)都呈现先下降再上升的变化趋势;中氮时,干旱处理和灌溉处理的冬小麦TCDP在开花期和灌浆期都呈现一直上升的趋势。无论高氮还是中氮、低氮,冬小麦直接辐射透过系数(TCRP)的值都随着天顶角角度的增大而减小,冬小麦TCRP的值随着冬小麦生育期的推进,都呈现出先下降、后上升的变化趋势。高、中、低氮3种情况下,干旱和灌溉处理的冬小麦每个生育期均呈现随着天顶角角度的增加,消光系数K也增大;高氮时,多数情况下,冬小麦冠层的消光系数K干旱的大于灌溉的;中氮、低氮时,多数情况下,冬小麦冠层的消光系数K干旱的小于灌溉的。干旱和灌溉对冬小麦冠层光分布的影响:灌溉增加了冬小麦的平均叶面倾角(MLA);干旱和灌溉处理条件下冬小麦的TCDP差异较小,TCDP与MLA变化趋势相似,也都呈现出先下降、再上升的变化规律;干旱和灌溉处理冬小麦TCRP,无论高氮还是中氮、低氮,都随着天顶角角度的增大而减小,在7.5°、22.5°时干旱和灌溉对冬小麦TCRP的影响较大,而在37.5°、52.5°、67.5°时对冬小麦TCRP的值影响很小;每个生育期消光系数K均随着天顶角角度的增加而增大。 相似文献
19.
北大西洋臭氧极小值和北太平洋极大值及其相互关系 总被引:2,自引:0,他引:2
利用1979~2002年TOMS卫星观测资料,采用臭氧总量纬向偏差和区域强迫的分析方法,研究北大西洋东北部大气臭氧低值与北太平洋西北部臭氧高值的季节变化过程和相互关系.研究表明,(1)北大西洋东北部存在一个大气臭氧极小值,年平均臭氧总量比纬向平均值低20 DU以上,冬季低50 DU以上; 北太平洋西北部存在一个大气臭氧极大值,年平均臭氧总量比纬向平均值高35 DU以上,冬季高70 DU以上.(2)上述两个地区大气臭氧的季节变化具有很强的区域特征,区域大气动力学输送和化学过程对上述两个地区大气臭氧季节变化的强迫分别为50.3%和42.6%.(3)上述两个地区大气臭氧纬向偏差的季节变化间存在很好的反相关,相关系数达到-0.98,说明其臭氧区域强迫之间存在良好的关系. 相似文献
20.
为揭示冬小麦干物质积累过程的动态变化,利用不同品种冬小麦分期播种的灌浆速率资料,建立了Logistic模型,定量分析了不同播期条件下不同品性冬小麦的灌浆特性,并探讨了冬小麦灌浆特性对气象因子的响应情况。结果表明,籽粒灌浆质量与开花后天数的关系符合Logistic生长曲线方程。基于Logistic模型求算的各次级参数能够较好地表征冬小麦籽粒灌浆特性,半冬性品种较春性品种灌浆高峰期出现时间早;春性品种的粒重渐增期和粒重快增期持续时间一般长于半冬性品种的;半冬性品种的平均活跃灌浆期较春性品种的短;早播和正常播种条件下,春性品种最大和平均灌浆速率均高于半冬性品种的,而迟播条件下春性品种最大和平均灌浆速率均低于半冬性品种的,适期晚播更利于春性品种灌浆和千粒重增加。灌浆特性的变异系数分布总体呈春性品种大于半冬性品种的,表明播期对春性品种的影响更大。不同籽粒灌浆特性对气象因子的响应不同,其中孕穗—成熟期内的平均气温、孕穗—乳熟期内的降水量、播种—乳熟期内的日照时数与冬小麦灌浆特性相关密切,基于灌浆特性与气象因子建立的逐步回归方程决定系数为0.507~0.875,均通过了0.01的显著性检验。 相似文献