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西江沿岸地带是一个工业不发达的待开发民族区域,但它拥有多方面工业资源优势,而且工业开发环境条件良好。作者认为,优势的工业资源开发必须在全方位开放与资源深度利用的基础上以轻型为主导的策略,重点建设制糖、水果加工、水电、有色金属为主的原材料及加工等若干工业基地。布局上以西江干流和区内铁路干线为“轴”,结合重点工业“点”,稳定提高中部,重点开发东部,创造条件开发西部,实现“点轴结合,逐步推进”的工业资源区域开发策略。 相似文献
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公众参与已成为环境影响评价的一项重要内容。可以让公众了解项目及其环境影响,并广泛征求公众对项目的意见:确保项目引起的重大环境问题在报告书中得到论证.并提出可行的环境保护措施。作在实际工作的基础上,总结出一套实用的公众参与的程序和方法,并应用于世行贷款西江下游航道整治工程环境影响评价中. 相似文献
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佛山市南海区里水镇位于佛山市东北部,东与广州接壤,西距佛山仅10多公里,广佛高速公路横贯而过,镇内的西江支流与广州直接通航,水陆交通方便快捷. 相似文献
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俗话说科学技术是第一生产力。对于现今的资源开发型企业而言,在市场竞争和资源紧缺的双重影响下,只有依靠不断地科技创新,不断地更新优化生产工艺,不断地淘汰落后的产能,不断地技术研发储备先进的发明专利,才能使企业,使产品在市场上站稳脚跟,才能实现可持续的发展。对于从事有色金属开发的江西江锂 相似文献
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安庆西江是长江江豚(Neophocaena asiaeorientalis asiaeorientalis)迁地保护的重要基地,为评估西江长江江豚饵料资源的供给能力,于2016年8月和2017年1月采用水声学探测与电捕取样相结合的方法,评估了西江水域鱼类群落结构和长江江豚可持续利用的鱼类资源。共采集到鱼类5目8科34种,夏季鱼类密度为1.4~5 662.3 ind./1 000 m3,均值为 253.3 ind./1 000 m3;冬季鱼类密度为0.8~2 338.1 ind./1 000 m3,均值为127.5 ind./1 000 m3。基于平均生物量和P/B-系数估算了西江鱼类生产力,并根据Y=0.5P对江豚可持续利用的饵料鱼产量进行了估算,西江可持续供长江江豚摄食的鱼类资源量约为 3 050~40 800 kg/a。为防止凶猛性鱼类种群过度发展与长江江豚争夺饵料资源,建议加强对西江鱼类群落的持续监测,并在必要时进行人工合理调控。
关键词: 西江;水声学;长江江豚;现存量;最大持续产量 相似文献
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Chlorobenzenes in waterweeds from the Xijiang River (Guangdong section) of the Pearl River 总被引:3,自引:0,他引:3
The Xijiang River is the major source of water for about 4.5 millions of urban population and 28.7 millions of rural population. The water quality is very important for the health of the rural population. The concentration and distribution of chlorobenzenes (CBs) in both water and waterweeds collected from 4 stations in the Xijiang River (Gangdong section) of the Pearl River in April and November were determined. The result showed that nearly every congener of CBs was detected. The total contents of CBs (∑CBs) in the river water ranged from 111.1 to 360.0 ng/L in April and from 151.9 to 481.7 ng/L in November, respectively. The pollution level of CBs in the water in April was higher than that in November. The contents of ∑ CBs in waterweeds ranged from 13.53×102 μg/g to 38.27×102μg/g dry weight (dw). There was no significant difference between April and November in waterweeds. The distribution of CBs in roots, caulis, and leaves of Vallisneria spiralis L. showed different patterns. The leaves mainly contained low-molecular-weight CBs(DCBs), whereas the roots accumulated more PCBs and HCBs. The average lgBCFlip (bioconcentration factor) of CBs ranged from 0.64 to 3.57 in the waterweeds. The spatial distribution character of CBs in the Xijiang River was: Fengkai County < Yunan County <Yun'an County < Gaoyao County according to the ∑CBs, and the pollution deteriorated from the upstream to the downstream of the Xijiang River. Further analysis demonstrated that the discharge of waste containing CBs may be the main source of CBs pollution in the Xijiang River. 相似文献