内江市沱江流域实现可持续发展的途径探讨$$$$##6研究方法

本文对内江市沱江流域经济-环境系统1995～2010年时段可持续发展进行了预测分析，指出了该区域实现可持续发展的可能途径和对策措施．     

岷江上游半干旱河谷土壤成土特征研究：以大沟流域为例

岷江上游半干旱河谷位于新构造运动活动带，其土壤形成和发育过程有着鲜明的区域特征。本文结合该区域的自然地理特点，综合分析各成土因素和土壤性状，对该区域土壤的成土特征进行了深入的分析和研究。     

渭河径流特性研究

由于工农业的快速发展,渭河径流逐年减少,污染加重,河道淤积不断发展,洪涝灾害时有发生,对中下游人民生产生活造成严重影响.为了减少洪害,减轻污染,必须保证渭河常年径流稳定.     

基于河网水系变化的水灾危险性评价——以永定河流域京津段为例

城市化过程中不合理的土地利用导致河道填塞、河网缩减现象普遍，城市水灾增加。基于灾害系统思想，构建了基于河网水系变化的水灾危险性评价体系，并以永定河京津段为例进行了实证分析。结果表明：（1）近40年来研究区水系结构简单化趋势明显，河道长度减少了20．5％，条数减少了36．4％，水系调蓄能力下降，在同样的致灾强度下水灾危险性加大；（2）在假设暴雨重现期为50年的条件下，经济密度差异决定了水灾潜在危险区的空间格局，居民用地将成为水灾重度危险区；平原段水灾重度危险区占5．7％，中度危险区占33．1％，滨海段重度危险区占13．9％，中度危险区占26．8％。研究结果可为区域综合减灾、水灾预报提供依据。     

塔河流域森林生态建设存在的主要问题及其策略

随着时间的推移,塔河流域生态环境恶化的现实已被越来越多的人们所认识。造成塔河中下游森林退化,生态环境恶化的主要原因除自然因素外,主要是人为不合理的社会经济活动的影响。目前塔河流域森林生态建设存在的主要问题有:第一水资源不合理的利用成为沙漠化和次生盐渍化的主要原因;第二传统的生活方式和掠夺式的生产方式使生态环境遭到破坏;第三耕地的增加,满足不了人口发展的需求,大面积的无序开荒,导致生态环境进一步恶化。为塔河中下游林地植被恢复、建设及防止退化的策略有:塔河中下游生态工程治理的原则;塔河中下游生态环境治理的基本思路;塔河流域生态环境治理的主要对策,合理利用水资源,坚持生产、生态建设并重,确保生态用水;要积极调整农村产业结构,正确处理林业和农业、林业和牧业以及林业和工业发展的关系;大力发展农村能源建设,从根本上解决农村薪材和生态保护之间矛盾;大力保护、恢复、发展荒漠林草植被,大力发展绿洲林业,建立荒漠生态环境和绿洲共同支撑的稳定的生态体系;积极实施林业生态工程和林果工程,建立较为完备和发达的生态和产业体系。     

新疆和田河绿色走廊演变机制及生态环境保护初析

和田河绿色走廊是塔里木盆地中南北穿越塔克拉玛干沙漠的三条绿色走廊之一，具有重要的政治经济、生态、交通意义。绿色走廊的演变受到构造运动、气候波动和人为干扰等因素的影响。其中，人为干扰是绿色走廊现代生态环境演变过程中最重要最活跃的控制因素。建议加强流域水资源总体规划与统筹管理，兼顾生产、生活和生态用水，逐步改变农村居民燃料能源结构，从而保护绿色走廊生态健康。     

塔里木河下游绿色走廊的生态问题与治理对策

从经济、军事和生态三个角度分析了保护塔里木河下游绿色走廊的必要性,概括了该区域的生态环境现状,即河水矿化度升高、地下水位下降从而导致植被的退化和沙漠化加剧的问题。最后提出了以水资源合理利用为前提和中心的治理对策。     

塔里木河中游段治理中的牧区水利建设

塔里木河中下游地区生态环境急剧恶化,最主要的原因是中游段河水近一半21×108m3被人为的散失,造成下游河水所剩无几,致使尾闾台特玛湖干涸。解决的根本办法是将中下游段两岸的农牧民迁出,实现人为耗水为零。近期切实可行的办法是积极开展牧区水利建设,改变牧业生产方式,集中高效利用塔河水资源,发展人工草地,改良天然草场,实现牧业生产生态环境的协调发展,人与自然和谐相处。     

NUTRIENT CONCENTRATION CRITERIA AND CHARACTERIZATION OF PATTERNS IN TROPHIC STATE FOR RIVERS IN HETEROGENEOUS LANDSCAPES1

ABSTRACT: A method is demonstrated for the development of nutrient concentration criteria and large scale assessment of trophic state in environmentally heterogeneous landscapes. The method uses the River Environment Classification (REC) as a spatial framework to partition rivers according to differences in processes that control the accrual and loss of algae biomass. The method is then applied to gravel bed rivers with natural flow regimes that drain hilly watersheds in New Zealand's South Island. An existing model is used to characterize trophic state (in terms of chlorophyll a as a measure of maximum biomass) using nutrient concentration, which controls the rate of biomass accrual, and flood frequency, which controls biomass loss. Variation in flood frequency was partitioned into three classes, and flow data measured at 68 sites was used to show that the classes differ with respect to flood frequency. Variation in nutrient concentration was partitioned at smaller spatial scales by subdivision of higher level classes into seven classes. The median of flood frequency in each of the three higher level classes was used as a control variable in the model to provide spatially explicit nutrient concentration criteria by setting maximum chlorophyll a to reflect a desired trophic state. The median of mean monthly soluble reactive phosphorus and soluble inorganic nitrogen measured at 68 water quality monitoring sites were then used to characterize the trophic state of each of the seven lower level classes. The method models biomass and therefore allows variation in this response variable to provide options for trophic state and the associated nutrient concentrations to achieve these. Thus it is less deterministic than using reference site water quality. The choice from among these options is a sociopolitical decision, which reflects the management objectives rather than purely technical considerations.     

GEOMORPHOLOGY OF STEEPLAND HEADWATERS: THE TRANSITION FROM HILLSLOPES TO CHANNELS1

Headwater streams comprise 60 to 80 percent of the cumulative length of river networks. In hilly to mountainous terrain, they reflect a mix of hillslope and channel processes because of their close proximity to sediment source areas. Their morphology is an assemblage of residual soils, landslide deposits, wood, boulders, thin patches of poorly sorted alluvium, and stretches of bedrock. Longitudinal profiles of these channels are strongly influenced by steps created by sediment deposits, large wood, and boulders. Due to the combination of small drainage area, stepped shallow gradient, large roughness elements, and cohesive sediments, headwater streams typically transport little sediment or coarse wood debris by fluvial processes. Consequently, headwaters act as sediment reservoirs for periods spanning decades to centuries. The accumulated sediment and wood may be episodically evacuated by debris flows, debris floods, or gully erosion and transported to larger channels. In mountain environments, these processes deliver significant amounts of materials that form riverine habitats in larger channels. In managed steepland forests, accelerated rates of landslides and debris flows resulting from the harvest of headwater forests have the potential to seriously impact the morphology of headwater streams and downstream resources.