Urban metabolic flow in China’s megacities doubled by material stock accumulation since the 21st century

IF 9.1 Q1 ENVIRONMENTAL STUDIES
Chenling Fu, Tianjie Deng, Yan Zhang
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Abstract

Buildings, infrastructure, and durable goods play a critical role in urbanization, akin to bones and muscles that structure the human body. These stocks contribute to the exploitation of over half of the world’s resources and offer potential “urban mining” sources. However, the process of resource transformation regarding urban material stock growth and material flow alteration remains unclear. The metaphor of urban metabolism provides a new perspective to dissect this process, but current studies often spotlight only specific fragments, such as certain end-use types or materials. This study bridges this gap by establishing a comprehensive level-to-level analysis of urban “bone-muscle” metabolism in China’s megacities. This study presents a comprehensive analysis of urban metabolism in China’s megacities, tracking the lifecycle of material stock across over a hundred distinct end-use types and 12 categories of materials. Results indicate that annual metabolic flow in these cities has doubled since the early 21st century, reaching 264–737 Mt in 2018, with manufacturing, construction, and transportation as primary drivers. As accumulation intensifies, the material stock’s growth rate diminishes logarithmically, hinting at increased efficiency and a move towards a steady state. Concurrently, scrap flow is on the rise. Driven by population growth, per capita scrap is projected to reach 2.0–4.7 t/cap by 2035, and material stock is expected to rise 1.4–2 fold. Proactive population planning and coordinated development strategies can mitigate the risks associated with this growth and maintain urban system stability.

Abstract Image

21 世纪以来,中国特大城市的城市代谢流量因物质存量积累而翻了一番
建筑、基础设施和耐用品在城市化进程中发挥着至关重要的作用,就像构成人体的骨骼和肌肉一样。这些存量有助于开发世界上一半以上的资源,并提供了潜在的 "城市采矿 "来源。然而,有关城市物质存量增长和物质流改变的资源转化过程仍不清楚。城市新陈代谢的隐喻为剖析这一过程提供了新的视角,但目前的研究往往只关注特定的片段,如某些最终用途类型或材料。本研究通过对中国特大城市的城市 "骨骼-肌肉 "新陈代谢进行全面的逐层分析,弥补了这一空白。本研究对中国特大城市的城市新陈代谢进行了全面分析,追踪了百余种不同最终用途类型和 12 类材料的生命周期。结果表明,自 21 世纪初以来,这些城市的年代谢流量翻了一番,2018 年达到 2.64-737 亿吨,其中制造业、建筑业和交通运输业是主要驱动力。随着积累的加剧,物质存量的增长率呈对数递减,暗示着效率的提高和向稳定状态的迈进。与此同时,废料流也在增加。在人口增长的推动下,预计到 2035 年,人均废料量将达到 2.0-4.7 吨/瓶,材料存量预计将增加 1.4-2 倍。积极的人口规划和协调的发展战略可以降低与这种增长相关的风险,并保持城市系统的稳定性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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