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摘要:基于成都市水生态现状,为提高其水生态承载力,促进经济发展和提高人民生活水平,运用系统动力学(SD)的方法,建立了成都市水生态-经济-人口-水资源-水环境的耦合系统,模拟了现状延续型、节约用水型、污染防治型和综合协调型四种情景模式。模拟结果显示:在模拟年限内(2014年-2020年),现状延续型和污染防治型未能有效降低水生态承载限制系数,水生态问题将进一步加剧;节约用水型和综合防治型都可以降低水生态承载限制系数,但节约用水型不能显著减低该系数,只有通过节约用水和污染防治相结合的综合防治型,才可以更加有效的减低该系数,该情景模式是提高水生态承载力的最佳模式;到2020年,该情景模式下成都市的水生态承载限制系数下降为0.297,与2010年的相比,下降了59.4%。研究结果可为成都市水生态保护提供技术依据。
关键词:SD模型;水生态承载力;决策变量;情景模拟
中图分类号:TV213 文献标识码:A 文章编号:1672-1683(2017)04-0101-10
Abstract:In order to enhance the water ecological carrying capacity of Chengdu city whilst promoting the development of economy and improving the living standards of the people,System Dynamics (SD)method was applied to build a coupled system of water ecology-economy-population-water resources-water environment of the city based on the status quo of water ecology.Four scenario patterns including status-continuing,water-saving,pollution-controlling,and integrated-coordination were simulated by the SD model.Simulation results showed that:in the analog period (2014 to 2020),the status-continuing and pollution-controlling scenario patterns can not effectively reduce the limit coefficient of water ecological carrying capacity,resulting in further deterioration of water ecological problems.However,the water-saving and integrated-coordination scenario patterns can reduce the limit coefficient of water ecological carrying capacity.It should be noted that the water-saving scenario pattern can not significantly reduce the coefficient.The integrated-coordination pattern combining water-saving and pollution-controlling measures can reduce the coefficient more effectively.It is the best pattern to improve the water ecological carrying capacity.With the aforementioned recommended pattern,the limit coefficient of water ecological carrying capacity can be reduced to 0.297 for Chengdu City by 2020,down by 59.4% compared with that of 2010.The research results can provide technical basis for water ecological protection in Chengdu city.
Key words:SD model;water ecological carrying capacity;decision variable;scenario simulation
系統动力学最初是由美国麻省理工学院Forrester教授所创立,20世纪70年代末引入我国。经过30多年来的发展,它几乎被应用于自然科学和人类社会的全部领域。当前,系统动力学在可持续发展和生态系统变化的预测研究中应用相当广泛[1],它作为系统科学理论与计算机仿真紧密结合、研究系统反馈与行为的一门科学,是系统科学与管理科学的一个重要分支[2]。我国的水生态承载力研究主要是沿着水资源承载力→水环境承载力→水生态承载力和环境承载力→生态承载力→水生态承载力这两条主线逐步发展起来的[3]。目前对水生态承载力定义的叙述,不同的学者对此表述不一。李靖[4]等将水生态承载力表述为在一定的历史阶段,某一流域的水生态系统在满足自身健康发展的前提下,在一定的环境背景下所能持续支持人类社会经济发展规模的阈值。彭文启[5]给出了水生态承载力的广义定义:流域水生态承载力指维持良好状态的流域水资源及水环境系统所能承受的一定水平的人口的最大数量和一定技术水平下的最大经济规模,从水资源、水环境等水体理化特性及水生态特征等方面考虑了水生态承载力的定义。