摘要
冠层截留是降雨过程中的水量分配和流域水平衡的一个重要组成部分,通过水浸泡法和降雨模拟实验研究呼伦湖流域草原3种放牧制度下(休牧、轮牧、自由放牧(超载放牧))植被冠层截留量的变化规律,并利用遥感解译植被归一化指数(NDVI),确定3种放牧制度下草原面积,估算呼伦湖流域草原降雨截留量。研究表明:在休牧、轮牧、自由放牧3种制度下,水浸泡法测定的截留量分别是0.468、0.320、0.271 mm。降雨模拟实验法测得的结果分别是0.957、0.613、0.431 mm。休牧、轮牧、自由放牧草场叶面积指数、盖度、容重、生物量等指标差异显著(P<0.05),且单株植被高度、鲜重对截留量影响显著呈线性正相关关系。呼伦湖流域草原一次降雨量为大于等于30 mm全流域降雨,其植被截留量为6.462×106m3。
Different grazing systems have different influences on the biomass, leaf area index (LAI) and canopy morphology of grassland vegetation. Canopy interception is an important part of both water allocation and the balance of water across the whole basin during precipitation. In this paper, water soakage and rainfall simulation methods were used to study the change in rainfall interception by the grass vegetation canopy under three different grazing systems : no grazing, rotation grazing and free grazing (over grazing), in the Hulun watershed, Inner Mongolia, China. We discuss the relationships between trends in individual plants and the vegetation interception as well as the trends between the overall plant height and weight measurements and vegetation interception. Satellite image data from Landsat TM5 were used to extract the Normalized Difference Vegetation Index (NDVI) of grassland in the Hulun watershed and the actual coverage of the no grazing, rotation grazing and free grazing grasslands. The relationship of actual coverage and NDVI was used to measure the grassland areas in the three grazing systems. Estimating the amount of rainfall interception of three different grazing grasslands in the Hulun watershed, even without considering the spatial and temporal variation of rainfall, can provide basic data for future basin water resources planning studies. The vegetation interceptions estimated by the water soakage method for no grazing, rotation grazing and free grazing grasslands were 0.468 mm, 0.320 mm and 0.271 mm, respectively. Those estimated by the rainfall simulation method were 0.957 mm, 0.613 mm and 0.431 mm, respectively. The predominant vegetation types having an interception advantage from three different grazing systems were; Stipa krylovii, Leymus chlnensis, Cleistogenes squarrosa and Artemisia firigida. In terms of leaf area proportion, the main interception species were Stipa krylovii and Cleistogenes squarrosa in free grazing, Stipa krylovii and Leymus chinensis in rotation grazing and Stipa krylovii with no grazing. The values of coverage, soil bulk density, biomass and LAI were significantly (P〈0.05) different among the three grazing systems. The LAI values were 4.36 m^2/m^2 with no grazing, 2.72 m^2/m^2 in rotation grazing and 1.37 m^2/m^2 in free grazing. The height and weight of individual plants were also linearly correlated with interception in the three grazing systems with vegetation interception increasing with the height and weight of individual plants. The height and weight of the plants overall was linearly correlated with interception in the no grazing and rotation grazing grasslands , where interception increased with a height and weight increase. There was no such trend in the free grazing grassland. The overall plant cover was linearly correlated with interception in all three grazing grasslands. The vegetation interception of the plants overall and the individual plants had obvious phenomenon grading in all three grasslands. Through field measurements in the Hulun watershed, the cover ranges of no grazing, rotation grazing and free grazing grasslands were 79%-98%, 57%-84% and 35%-62%, respectively. Thus, the total canopy interception in the Hulun watershed will be 6.462 × 10^6 m^3 and the canopy interception of the different grazing systems will be 4.995 × 10^5 m^3 with no grazing, 3.283 × 10^6 m^3 with rotation grazing and 2.679 × 10^6 m^3 with free grazing if the whole basin rainfall reaches 30 mm.
出处
《生态学报》
CAS
CSCD
北大核心
2015年第14期4716-4724,共9页
Acta Ecologica Sinica
基金
国家自然科学基金项目(51169011
51169017
51269016
51269017
51339002)
内蒙古自治区自然科学基金项目(2012MS0612)
高等学校博士点基金新教师类项目(20131515120005)
对发展中国家科技援助项目
关键词
呼伦湖流域
不同放牧制度
冠层截留
降雨模拟
Hulun watershed
different grazing systems
grass interception
rainfall simulation