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1、封面位置(预留)最新自动排版信息请关注微信公众号WordPB如果有封面,排版结束最后添加(不要删除下面的分节符);无封面请直接删除本节摘 要封面部分请在独立的文档中手工设置,软件主要用于正文部分的处理,文中的颜色是为了便于检查打印时去除本文于2007年4月-9月,采用热扩散液流法(TDP)试验观测了华北平原农区杨树农田防护林内24年生毛白杨林带蒸腾速率、采用自动气象观测系统观测了林带内农田小气候参数、采用TDR技术观测了土壤含水量、采用PenmanMonteith模型测算了林带内作物(冬小麦/夏玉米)蒸腾量,从林带蒸腾变化规律及其影响机制、防护林内作物蒸腾变化特征及其与开阔农田作物的差异、林带
2、与作物耗水比例关系,分析了华北平原杨树农田防护林系统主要生长期耗水特征,以期为该地区农田防护林及农林复合系统的可持续发展提供必要的理论依据。1、林带蒸腾变化规律及其影响机制杨树蒸腾日际或月份变化变化趋势是:杨树蒸腾量从4月份开始逐渐升高,5月份由于林网内农作物灌溉量加大的影响,与6、7月份基本持平,并达到全年最高峰,89月份逐渐降低。2007年杨树在生长季(49月)蒸腾耗水总值为488.02mm,各月耗水量所占生长季总耗水量的比例:11.17、18.71、19.30、19.29、16.66、14.88。Tr=0.240*Ta-0.035*RH+0.007*Q+0.0260*V-0.734,R2
3、=0.822(=0.01)杨树蒸腾速率与叶面积指数的关系则表现为幂函数:Tr=0.2568LAI1.8392,R2=0.8337。2防护林内作物蒸腾变化特征及其与开阔农田作物的差异防护林内冬小麦蒸腾与开阔农田在不同生育期变化趋势基本一致,在拔节抽穗期,耗水量较小,扬花灌浆期耗水量达到最大,成熟期耗水量有所降低。其中,系统内外日平均耗水量在拔节期分别为2.45mm/d、3.23mm/d,扬花灌浆期分别为2.68mm/d、3.90mm/d,成熟期分别为为2.61mm/d、3.20mm/d;系统内外耗水量在拔节期分别只占主要生长期(拔节到成熟期)耗水的33.18%、31.97%,扬花灌浆期为51.4
4、6%、48.30%,成熟期为18.52%、16.57%。总体而言,冬小麦在拔节到成熟期,系统内外冬小麦的耗水量分别为:212.14mm、155.18mm,复合系统内冬小麦的耗水量降低了26.85%,在a0.01水平上二者差异显著。3、林带与作物耗水比例关系从4月到9月生长季节,在实际区域面积上,复合系统中冬小麦与杨树蒸腾耗水量的比值为4.8:1,夏玉米与杨树蒸腾耗水量的比值为8.9:1,说明作物耗水是杨树农田防护林系统耗水的主要特征方式,从合理利用水资源的角度而言,该地区适度发展该类农田杨树农田防护林或宽带距杨农复合系统是可行的。关键词:华北平原 杨树农田防护林系统 冬小麦 夏玉米 蒸腾耗水V
5、AbstractWith the thermal dissipation probe(TDP) method and the Penman-monteith modle, the transpiration of 24-year-old poplar (Populus tomentosa Carr.)and the crop(Triticum aestivum L. & Zea mays L.) were measured and estimated in the poplar sheltbelts over a period from April to September in the Cr
6、opland of North China Plain.Meanwhile,the parameter of microclimate in the sheltbelts were observed by the automatic weather station system.The water consumption characteristics of the poplar-crop systems in the cropland of North China Plain were analyzed form three aspects:英文字体为Times New Roman1、The
7、 rules of the variation of the poplar belts transpiration and the mechanism of its influenceIn every month during the growing seasons of 2007,Tr showes significantly compound correlated with the solar radiation(Q), air temperature(Ta), air relative humidity(RH) and wind speed(V) (=0.01),and Ra is th
8、e most important meteorology factor effecting on Tr though comparing the partial coefficient. In the growing months(4-9),the multivariate linear model between Tr and the meteorological factors is:Tr=0.240*Ta-0.035*RH+0.007*Q+0.0260*V-0.734 R2=0.822And the relationship between Tr and the poplars LAI
9、is described by the power function: Tr=0.2568LAI1.8392 ,R2=0.8337.2、The variation of the crops transpiration(Tr) in the sheltbelts and in the open croplandFor the wheat, the variations of the Tr in the sheltbelts is consistent with the Tr in the open cropland in different growth period. The Tr is lo
10、wer in the shooting phase,and reaches the highest in the grain-filling phase, decreases in the mature phase. Concretely, the daily mean Tr in the sheltbelts and in the open cropland is 2.45mm/d and 3.23mm/d respectively in the shooting phase, 2.68mm/d and 3.90mm/d in the graining-filling phase,2.61m
11、m/d and 3.20mm/d in the mature phase.And the rate of the Tr to the main growth period in sheltbelts and in open cropland is 33.18% and 31.97% respectively in shooting phase, 51.46% and 48.30% in the graining-filling phase, 18.52% and16.57% in the mature phase. From the shooting to the mature phases,
12、 the Tr of the wheat in the sheltbelts and the open cropland are 212.14mm and 155.18mm respectively, the intercropping significantly reduces the Tr by 26.85%(=0.01) compared with monoculture system.3、The relation of water consumption proportion between belt and the crop:In the main growing months(4-
13、9), the water consumption ratio of the winter wheat to the poplar belts is 4.8:1,for the summer maize,its 8.9:1,it showes that the water consumption ratio of the crop is the main features of the poplar-crop system,and it is feasible to develop the broad-row poplar-crop system in the cropland of Nort
14、h China.Keywords: North China Plain, Poplar Sheltbelts System , wheat, maize, transpiration目 录摘 要IIAbstractIII目 录V第一章 绪 论(黑体小三,20磅行距,段前20磅,段后14磅)11.1 引言(黑体四号,20磅行距,段前12磅,段后8磅)11.1.1 研究背景(黑体小四,20磅行距,段前8磅,段后4磅)11.1.2 研究目的和意义11.1.3 项目来源与经费支持21.2 国内外研究现状与评述21.2.1 国内外农林复合系统实践与研究概况21.2.2 农林复合系统耗水特征的研究(三级标
15、题段前段后各0.5行)41.2.3 植物蒸腾及蒸散测算方法61.2.4 研究评述(三级标题段前段后各0.5行,靠左)91.3 研究目标和主要研究内容91.3.1 研究目标91.3.2 主要研究内容91.4 研究技术路线10第二章 研究材料与方法(格式要求与上相同)112.1 试验地概况112.2 试验材料与内容112.2.1 试验材料112.2.2 观测内容与方法112.2.3 防护林内试验布设示意图15第三章 结果与分析163.1 杨树林带蒸腾耗水特征163.1.1 杨树蒸腾耗水的时间变化规律163.1.3 小结18参考文献20在读 期间的学术研究21致 谢22沈阳工业大学本科生毕业论文(设计)第一章 绪 论(黑体小三,20磅行距,段前20磅,段后14磅)1.1 引言(黑体四号,20磅行距,段前12磅,段后8磅)1.1.1 研究背景(黑体小四,20磅行距,段前8磅,段后4磅)要获得理想的排版效果,段落建议按照 第章 1.1 1.1.1 (1) 1)等数字严格编号。并控制标题行在适当的长度内(默认参数为50字符)农林复合系统或称复合农林业(Agroforestry)既是一种传统而新兴的土地利用方式,又是一门新型的交叉型研究领域。自20世纪70年代,由于“人口剧增、粮食短缺、资源危机、环境恶化”等全球性问题的出现,促
