厦门市资源水与虚拟水耦合代谢效率评价

自然水循环与社会水循环的关联研究是制定系统性水代谢对策的前提。从水资源代谢过程与格局角度,用物质流分析法(MFA)剖析了亚热带季风气候雨影区缺水城市枯水年份资源水与虚拟水耦合代谢的路径、数量,提取代谢效率评价所需的过程与结构指标,以社会、经济、生态环境效益最优化为评价原则构建了城市水资源代谢效率评价指标体系,采用层次分析法赋权,评价了近10年来枯水年份厦门市资源水与虚拟水耦合代谢效率。结果表明,厦门水资源代谢效率呈加速提高趋势,主要由用水效率类和水代谢过程与结构类指标驱动。说明提高水资源代谢效率的根本对策在于用水行为和用水过程与结构的改善。采用情景分析法设计主导驱动指标不同组合下水资源代谢效率情景方案,提高了方案的可操作性,可基于这些指标制定水资源管理对策。基于MFA结果提取指标丰富了指标体系构建理论。     

城市物质代谢的生态效率——以深圳市为例

城市可持续发展研究的关键是城市物质代谢通量及其效率研究,但物质代谢通量仅能反映代谢速率,而其生态效率则能反映支持社会经济发展的物质代谢能力。从工业、生活的源头循环(减少原生资源的消耗)和末端循环(减少污染物的产生)角度,构建城市物质代谢生态效率的度量模型,并依据中国城市化发展进程,选定深圳市作为研究区,核算城市水、能量和废物代谢通量以及代谢的生态效率。结果表明:随着深圳市社会经济的快速发展,水、能源和废物代谢通量呈现出增长势头,但代谢的生态效率不断提高。1998～2004年间,GDP增长2.7倍,城市水和电的代谢通量分别增长1.5倍和3.0倍;工业增加值增长3.7倍,工业水、电、能源和废物的代谢通量分别增长1.9、3.5、2.7倍和2.0倍;常住人口增长1.5倍,居民水和电的代谢通量分别增长1.8倍和1.7倍;资源效率提高1.8倍,环境效率提高3.7倍,生态效率提高2.3倍。虽然深圳市物质代谢的生态效率在提高,但是随着物质资源的日益稀缺,物质代谢的生态效率仍需进一步提高,而提高城市物质代谢生态效率的关键是资源效率和环境效率的协同发展,以及逐步构建废物资源化的循环链条。     

不同水氮条件下骆驼刺幼苗生长及氮效率变化特征

在荒漠生态系统氮沉降背景下,研究退化植被幼苗对水分和氮素变化的响应特征,对实现植被恢复和重建具有重要意义。在塔里木盆地南缘对骆驼刺（Alhagi sparsifolia）幼苗通过2年的水分（干旱、中水和湿润）和氮素（不施氮、低氮（51 mg/kg）、中氮（102 mg/kg）和高氮（306 mg/kg））添加试验,研究骆驼刺幼苗干物质累积、生物固氮和氮效率对水氮条件变化的响应。结果表明,骆驼刺幼苗不同器官的干物质累积和吸氮效率对水氮条件变化的响应因生长年份而异,但幼苗整株干物质累积和吸氮效率在2个生长年份的变化趋势却相似。在干旱条件下,骆驼刺幼苗的干物质量、吸氮效率和生物固氮量均在低氮处理下显著增加,之后随施氮量增加而降低。水氮交互可显著提高幼苗干物质累积、吸氮效率和生物固氮量,其中以中水中氮处理的效果最好。水氮添加有降低骆驼刺幼苗氮素利用效率（NUE）的趋势,但在干旱和中水条件下施氮可显著提高幼苗的生物固氮比例,然而生物固氮比例与NUE仅在第2个生长年份呈显著负相关。在2个生长年份,骆驼刺幼苗干物质量与吸氮效率和生物固氮量呈极显著正相关关系,但与NUE和生物固氮比例并无明显相关性。这表明骆驼刺幼苗主要是通过调节吸氮效率和生物固氮量来适应水氮条件变化,进而影响幼苗干物质累积。     

京津冀城市群人-地、人-水与人-碳交互胁迫关系及其叠加效应

随着社会、经济效益的不断增加及国际影响力的不断增大,京津冀正在向世界级城市群迈进。而快速的城市增长与资源环境的交互胁迫效应严重制约了京津冀地区的可持续发展,因此,明确城市增长与不同资源环境要素的相互作用机制并采用有效的措施,是实现京津冀地区发展和保护共生的关键。目前针对城镇化与单一种资源环境要素交互作用的研究较多,但对城镇化与不同资源环境要素相互作用的叠加效应的关注很少。针对土地、水资源与能源这三种明显限制京津冀地区发展的资源要素,综合考虑了供给侧与需求侧特征,分析了人-地、人-水与人-碳的相互作用关系,解析了京津冀地区城镇发展与不同资源环境要素交互胁迫作用及其叠加效应。结果表明：2002-2017年,1、城市群整体水平上,人-地、人-水和人-碳关系总体上均呈"强协调"或"弱协调"交替变化的状态;2、城市尺度上,不同城市的人-地、人-水和人-碳交互关系存在明显时空分异。多数城市都曾面临土地、水资源或能源的胁迫影响,尤其是河北的一些城市（石家庄、邯郸、承德、衡水、邢台、唐山及保定等）在有些年份面临土地、水资源或能源的"强胁迫"影响;3、从京津冀地区整体水平上看,不存在多种资源要素的叠加胁迫影响,但是,城市群内部多数城市在有的年份同时面临土地、水资源或能源两种以上资源要素的叠加胁迫影响。因此,要协同改善京津冀地区资源环境的胁迫,需要全面考虑不同空间尺度之间,不同城市之间,以及不同资源要素之间的叠加影响机制,有针对性的提出政策与措施。     

我国茶叶产业生态效率与生产效率评价研究——基于DEA 方法的实证分析

生态效率是经济与环境协调发展的有效测度, 是可持续发展的重要评价指标。基于DEA 模型的实证研究, 分析了我国18 个产茶省份2004-2013 年的生产效率与2009-2013 年的生态效率。研究结果表明: 我国茶叶产业有较高的生产效率, 但茶叶产业的生态效率较低, 存在从事茶业劳动力冗余较多, 水资源和土地资源资源消耗过大, 利用效率不高, 经济效益不佳的问题。因此强化茶业劳动人员的技术知识, 减少农村剩余劳动力, 提高资源能源的利用效率, 提升茶叶产业的经济效益是改善我国茶叶产业生态效率, 使我国茶叶产业健康可持续发展的重要途径。     

好氧反硝化细菌碳氮代谢特点及途径的研究进展

好氧反硝化作用的发现打破了反硝化只能在严格厌氧条件下进行的传统认知,为生物脱氮提供了一条新的途径,已成为近些年的研究热点。碳源可为好氧反硝化过程提供能量和电子供体,其代谢难易程度直接影响着好氧反硝化细菌的脱氮效率,因此有必要明确碳源在好氧反硝化脱氮过程中的代谢机理。基于此,本文阐述了好氧反硝化细菌的种类及其对硝态氮与亚硝态氮的代谢途径;系统分析了不同好氧反硝化细菌对碳氮源代谢的差异与代谢机理;综合分析了碳代谢差异对好氧反硝化脱氮过程的影响,并对未来的研究方向进行了展望,旨在深入理解好氧反硝化细菌同时去除碳氮的机理,为提高废水生物脱氮除碳效率提供理论依据。     

中国生态地理区城市水资源利用效率时空分异特征

我国水资源面临的形势十分严峻,水资源短缺、水污染严重、水生态环境恶化等问题突出,已成为制约社会经济可持续发展的主要瓶颈。基于分类数据包络分析（Categorical DEA）对2007-2016年中国生态地理区城市水资源利用效率进行测算,对其时间变化、空间分布以及空间收敛性进行分析。结果表明：1）2007-2016年期间全国城市水资源利用效率总体处于低效率状态,随时间高低交错波动式发展,整体呈先降后升势态;2）生态地理区城市水资源利用综合效率由高到低依次为温带干旱区、温带半干旱区、温带半湿润区、温带湿润区、亚热带湿润区,呈西北向东南逐渐递减的空间分布格局,生态地理区纯技术效率区间差异较大,但空间分布规律不显著,区域规模效率间差距小,且无明显空间分布规律;3）纯技术效率低效是制约全国水资源利用综合效率提升的主要因素,生态地理区间纯技术效率巨大差距导致全国纯技术效率整体低效,也是全国水资源利用综合效率低效的根本原因;4）生态地理区水资源利用综合效率区域差距逐渐缩小,主要是因为高效率区域效率值向低效率区域靠拢,区域间低效向高效的"追赶效应"不明显。     

不同小麦品种氮效率和产量性状的研究

对29个冬小麦品种进行子粒产量和氮效率的研究,结果表明,在氮胁迫条件下,供试小麦品种的子粒产量具有明显差异。缺氮条件下子粒产量的聚类分析结果表明,供试品种可划分为氮高效、中效和低效三类,氮高效品种在其中所占比例较少。在缺氮条件（N-）下,不同氮效率品种成熟期植株全氮含量差异不大,植株氮素积累量、氮效率（NUE）、吸收效率（UPE）和利用效率（UTE）均以氮高效品种最高,中效品种次之,低效品种最低。缺氮条件下较强的氮索吸收和利用能力是氮高效小麦品种氮胁迫条件下高氮效率的主要原因。     

基于能值分析的厦门城市代谢可持续性评估

生态城市建设是中国城市转型发展的关键节点,对中国生态文明和新型城镇化发展具有推动作用。研究以中国典型的生态城市厦门市为例,基于城市代谢框架结合能值分析法,对厦门市代谢系统进行各项能值流的核算,构建2010-2017年厦门市能值指标评估体系,选用可持续发展指数、可持续发展能值指标、城市健康水平能值指数3项指标综合评价其生态可持续性,选取部分能值指标与珠海市、深圳市进行对比分析,以期为中国生态城市的可持续发展提供科学参考。结果表明：（1）2010-2017年,厦门市总能值呈上升趋势,2017年的总能值为2.51×10²⁴ sej,是2010年总能值的1.65倍,货币流能值显著增加,废弃物流能值下降。能值自给率由98.30%逐渐递增至99.20%,能值产出率由8.30%逐渐递增至15.20%,环境承载率小于3,属于环境低负荷状态。（2）厦门市可持续发展指标处于1-10之间,表明其生态经济系统具有活力和发展潜力,可持续发展能值指标由2010年的3.67增加至2017年的7.76,表明厦门市的可持续发展性能愈来愈好,城市健康水平能值指数由2010年的6.21上升至2017年的25.80,表明厦门市生态系统处于健康可持续发展的状态。（3）厦门市与珠海市、深圳市的能值指标对比分析表明,厦门市与珠海市均处于富有经济活力与生态可持续发展潜力阶段,且厦门市代谢系统的可持续发展水平整体优于珠海市与深圳市。（4）总体来看,厦门城市代谢系统处于可持续发展阶段,生态城市的建设有利于厦门市实现生态经济的可持续发展,研究对同类型生态城市的建设与可持续发展具有理论参考价值。     

城市生态系统氮代谢研究进展

城市氮代谢是当前城市物质代谢研究领域中的一个研究热点,其研究框架是将城市视为一个可进行氮代谢的生态系统整体,重点关注人类活动对城市人为活化氮代谢过程的影响及其可能产生的环境问题。本文在阐述城市氮代谢内涵、研究背景的基础上,介绍了物质流分析方法研究城市氮代谢的进展,分析了系统动态模型在城市氮代谢模拟研究中应用前景;最后从城市内部的氮代谢分析、工业氮在城市氮代谢中的归宿、氮足迹概念在城市氮代谢过程研究中运用等方面,探讨了未来城市氮代谢研究趋势与发展方向。实现不同尺度的城市氮代谢过程的准确分析,关键在于研究区域边界和氮流归宿的明确,而目前中国针对城市氮代谢分析研究很少,因此,有必要探讨适合城市氮代谢研究的多尺度分析方法及评价指标,以期为减少城市人为活化氮的排放提供理论参考。     

城市复合生态系统中互动关系的测度与评价

基于城市复合生态系统原理和城市代谢功能,构建了城市系统互动分析指标体系。应用因子分析法、层次分析法及所建立的量化模型,对城市复合生态系统中的不同变量之间的相关性和协调性进行度量。并以中国北京、上海、广州、天津、重庆和深圳等六大城市为例,对其可持续发展进程进行横向比较。结果表明,六大城市发展度由大到小的顺序是:上海、深圳、广州、天津、北京、重庆;协调度由好到坏的排序是:重庆、上海、广州、北京、天津、深圳;循环度由好到坏的排序是:深圳、上海、天津、北京、广州、重庆;从可持续发展度看,建设和实现可持续发展城市或生态城市的先后顺序大致为:上海、深圳、广州、重庆、天津、北京。说明城市可持续发展的关键取决于社会经济活动压力源的削减、自然生态环境的保育以及城市代谢功能的增强。     

Eco-efficiency of urban material metabolism: a case study in Shenzhen, China

The keys of studying urban sustainable development are material metabolism flux and efficiency. Metabolism flux of urban materials can only reflect the metabolism velocity, while its eco-efficiency can determine the metabolism capacity to support socio-economic development. The general model and the measure model of the eco-efficiency were set up, based on the source recycle (decreasing the consumption of crude resources) and the terminal recycle (decreasing the discharge of pollutants) of production and life. These models were employed to study material metabolism flux and efficiency in Shenzhen, China. Results showed that water, energy and waste metabolism fluxes have increased since 1998 with constant socio-economic development, and their eco-efficiencies have also increased rapidly. When GDP rose by 2.7 times, the metabolism fluxes of urban water and electricity rose by 1.5 and 3.0 times, respectively. When the added value of industry rose by 3.7 times, the metabolism fluxes of industrial water, electricity, energy and waste rose by 1.9, 3.5, 2.7 and 2.0 times, respectively. When population rose by 1.5 times, the metabolism fluxes of residential water and electricity rose by 1.8 and 1.7 times, respectively. During the period, the resource efficiency, environmental efficiency and eco-efficiency rose by 1.8, 3.7 and 2.3 times, respectively. Whereas the efficiency of material metabolism has been improved in Shenzhen, the scarcity of material resources has become more and more serious. Therefore, it is necessary to further improve the efficiency of material metabolism. The keys of improving the eco-efficiency of urban material metabolism are the increasing of resource and environmental efficiencies, and the establishing of the recycling chain of re-utilization of waste resources.     

Eco-efficiency of urban material metabolism: a case study in Shenzhen, China

The keys of studying urban sustainable development are material metabolism flux and efficiency. Metabolism flux of urban materials can only reflect the metabolism velocity, while its eco-efficiency can determine the metabolism capacity to support socio-economic development. The general model and the measure model of the eco-efficiency were set up, based on the source recycle (decreasing the consumption of crude resources) and the terminal recycle (decreasing the discharge of pollutants) of production and life. These models were employed to study material metabolism flux and efficiency in Shenzhen, China. Results showed that water, energy and waste metabolism fluxes have increased since 1998 with constant socio-economic development, and their eco-efficiencies have also increased rapidly. When GDP rose by 2.7 times, the metabolism fluxes of urban water and electricity rose by 1.5 and 3.0 times, respectively. When the added value of industry rose by 3.7 times, the metabolism fluxes of industrial water, electricity, energy and waste rose by 1.9, 3.5, 2.7 and 2.0 times, respectively. When population rose by 1.5 times, the metabolism fluxes of residential water and electricity rose by 1.8 and 1.7 times, respectively. During the period, the resource efficiency, environmental efficiency and eco-efficiency rose by 1.8, 3.7 and 2.3 times, respectively. Whereas the efficiency of material metabolism has been improved in Shenzhen, the scarcity of material resources has become more and more serious. Therefore, it is necessary to further improve the efficiency of material metabolism. The keys of improving the eco-efficiency of urban material metabolism are the increasing of resource and environmental efficiencies, and the establishing of the recycling chain of re-utilization of waste resources.     

Quantifying a virtual water metabolic network of the Metropolitan District of Quito,Ecuador using ecological network methods

Current human population is mostly located in urban areas making cities the center of attention in terms of achieving sustainability goals. Evidence shows that ecosystems have evolved over time toward a balanced configuration between resource efficiency and functional redundancy. For this reason, they are exemplary models to follow in terms of sustainability. Here, we apply similar ecological network-based methods to study the virtual water metabolic network (VWMN) of the Metropolitan District of Quito. The VWMN was obtained using novel bottom-up, survey-based methods to generate the urban metabolic network. We compare the VWMN results with those previously obtained from ecological food webs, to learn if there are insights about the sustainability of urban metabolic processes. We conclude that VWMN does not exhibit characteristics observed in sustainable ecological networks because this socioeconomic network exhibits higher levels of path redundancy. Urban metabolism studies are gaining in popularity as a research tool aimed at informing resource management and this is one of the first covering a city in the Global South and using a bottom-up survey method.     

Enabling Future Sustainability Transitions

This synthesis article presents an overview of an urban metabolism (UM) approach using mixed methods and multiple sources of data for Los Angeles, California. We examine electric energy use in buildings and greenhouse gas emissions from electricity, and calculate embedded infrastructure life cycle effects, water use and solid waste streams in an attempt to better understand the urban flows and sinks in the Los Angeles region (city and county). This quantification is being conducted to help policy‐makers better target energy conservation and efficiency programs, pinpoint best locations for distributed solar generation, and support the development of policies for greater environmental sustainability. It provides a framework to which many more UM flows can be added to create greater understanding of the study area's resource dependencies. Going forward, together with policy analysis, UM can help untangle the complex intertwined resource dependencies that cities must address as they attempt to increase their environmental sustainability.     

基于灰水足迹的中国城市水资源可持续利用综合评价

随着城市化的快速发展,中国城市水资源面临着水资源短缺与水环境恶化等挑战,因此加强城市水资源可持续利用对于中国可持续发展具有重要意义。基于灰水足迹核算对2016年中国地级市水资源可持续利用情况进行综合评价。研究结果表明：（1）中国城市灰水足迹水平差异大,平均值为23.40×10⁸ m³,主要集中在20.00×10⁸ m³以下。中国城市农业源灰水足迹比例占比主要在70%以上,工业源比例占比主要在20%以下,而生活源比例占比在40%以下;（2）全国灰水经济生产率在12.45-857.31元/m³范围内,地区差异明显。33%城市灰水足迹荷载系数均大于1,全国地级市灰水足迹荷载系数平均值为1.16,城市水资源利用已对水环境产生污染压力,用水不可持续;（3）城市水资源开发率与灰水足迹荷载系数呈一定程度的正相关关系,说明了城市发展对水资源利用的"量"和"质"的压力作用具有一定的协同关系;（4）水资源可持续利用程度呈现大型城市 > 特大型城市 > 超大型城市 > 中小型城市,城市发展一定程度上有助于水资源的可持续利用,但发展规模过大可能会造成用水高产而护水低效的现象。因地制宜的实行水资源循环经济发展模式以及适时纳入灰水足迹核算与管理体系,是当前城市化大背景下实现水资源可持续利用的重要途径。     

The Changing Metabolism of Cities

Data from urban metabolism studies from eight metropolitan regions across five continents, conducted in various years since 1965, are assembled in consistent units and compared. Together with studies of water, materials, energy, and nutrient flows from additional cities, the comparison provides insights into the changing metabolism of cities. Most cities studied exhibit increasing per capita metabolism with respect to water, wastewater, energy, and materials, although one city showed increasing efficiency for energy and water over the 1990s. Changes in solid waste streams and air pollutant emissions are mixed.
The review also identifies metabolic processes that threaten the sustainability of cities. These include altered ground water levels, exhaustion of local materials, accumulation of toxic materials, summer heat islands, and irregular accumulation of nutrients. Beyond concerns over the sheer magnitudes of resource flows into cities, an understanding of these accumulation or storage processes in the urban metabolism is critical. Growth , which is inherently part of metabolism, causes changes in water stored in urban aquifers, materials in the building stock, heat stored in the urban canopy layer, and potentially useful nutrients in urban waste dumps.
Practical reasons exist for understanding urban metabolism. The vitality of cities depends on spatial relationships with surrounding hinterlands and global resource webs. Increasing metabolism implies greater loss of farmland, forests, and species diversity; plus more traffic and more pollution. Urban policy makers should consider to what extent their nearest resources are close to exhaustion and, if necessary, appropriate strategies to slow exploitation. It is apparent from this review that metabolism data have been established for only a few cities worldwide, and interpretation issues exist due to lack of common conventions. Further urban metabolism studies are required.     

城市代谢研究评述:内涵与方法

随着城市发展面临的生态问题日益显著,部分研究者试图通过对自然生态系统进行类比来寻求解决途径,城市代谢理论应运而生。当以系统科学来研究城市生态系统时,哲学思想的引入为探索和城市及城市代谢的内涵提供了最原始的桥梁。因此,在介绍城市代谢内涵与研究进展的基础上,融合产业、家庭、社会等多尺度代谢理论,对城市代谢的边界进行扩展,将其分为狭义与广义两类,结合亚里士多德的"四因说"对其质料因(组分)、形式因(结构)、动力因(驱动力)和目的因(功能)进行识别分析,据此将城市代谢研究方法归纳为质料、形式和混合研究方法三类,并提出未来研究的主要动向和解决手段。城市代谢"四因图"可为相关研究者提供参考。